Wireless charging device and method, and device to be charged

ABSTRACT

The present disclosure provides a wireless charging device and method, and a device to be charged. The wireless charging device includes a first communication control circuit. The device to be charged includes a second communication control circuit and a battery. The first communication control circuit performs wireless communication with the second communication control circuit during wireless charging of the battery. The wireless communication may be one or more of Bluetooth communication, Wi-Fi communication, short-range wireless communication based on a high carrier frequency, optical communication, ultrasonic communication, ultra-wideband communication and mobile communication.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application is a continuation of International Application No.PCT/CN2018/082013, filed on Apr. 4, 2018, which claims priority toInternational Application No. PCT/CN2017/079784, filed on Apr. 7, 2017,and International Application No. PCT/CN2017/080334, filed on Apr. 13,2017, the entire contents of all of which are incorporated herein byreference in their entireties.

TECHNICAL FIELD

The present disclosure relates to a wireless charging technology field,and more particularly, to a wireless charging device, a wirelesscharging method and a device to be charged.

BACKGROUND

At present, in the charging technology field, a device to be charged istypically charged in a wired charging mode.

Taking a mobile phone as an example, the mobile phone is typicallycharged in a wired charging mode. In detail, when there is a need tocharge the mobile phone, the mobile phone may be coupled with a powersupply device via a charging cable (for example, a USB (universal serialbus) cable), and an output power of the power supply device may betransmitted to the mobile phone via the charging cable, to charge abattery in the mobile phone.

For the device to be charged, it needs to use the charging cable in thewired charging mode, which results in cumbersome operation in a chargingpreparation stage. Thus, a wireless charging mode has been favored moreand more by people. However, the conventional wireless charging mode hasa bad effect, and needs improvement.

SUMMARY

In an aspect, a wireless charging device is provided. The wirelesscharging device includes: a communication control circuit, configured toperform wireless communication with a device to be charged during thewireless charging of the device to be charged.

The communication control circuit includes any one or more of thefollowing modules for performing the wireless communication with thedevice to be charged: a Bluetooth module, a Wi-Fi module, a short-rangewireless communication module based on a high carrier frequency, anoptical communication module, an ultrasonic communication module, anultra-wideband communication module and a mobile communication module.

In another aspect, a device to be charged is provided. The device to becharged includes: a battery; a communication control circuit, configuredto perform wireless communication with a wireless charging device duringwireless charging of the battery.

The communication control circuit includes any one or more of thefollowing modules for performing the wireless communication with thewireless charging device: a Bluetooth module, a Wi-Fi module, ashort-range wireless communication module based on a high carrierfrequency, an optical communication module, an ultrasonic communicationmodule, an ultra-wideband communication module and a mobilecommunication module.

In another aspect, a wireless charging method is provided. The wirelesscharging method is applicable to a wireless charging device. The methodincludes:

performing wireless communication with a device to be charged duringwireless charging of the device to be charged.

The wireless communication includes any one or more of Bluetoothcommunication, Wi-Fi communication, short-range wireless communicationbased on a high carrier frequency, optical communication, ultrasoniccommunication, ultra-wideband communication and mobile communication.

In another aspect, a wireless charging method is provided. The wirelesscharging method is applicable to a device to be charged. The methodincludes:

performing wireless communication with a wireless charging device duringwireless charging of a battery in the device to be charged.

The wireless communication may include any one or more of Bluetoothcommunication, Wi-Fi communication, short-range wireless communicationbased on a high carrier frequency, optical communication, ultrasoniccommunication, ultra-wideband communication and mobile communication.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram illustrating a conventional wireless chargingsystem.

FIG. 2 is a block diagram illustrating a wireless charging systemprovided by an embodiment of the present disclosure.

FIG. 3 is a block diagram illustrating a wireless charging systemprovided by another embodiment of the present disclosure.

FIG. 4 is a block diagram illustrating a wireless charging systemprovided by yet another embodiment of the present disclosure.

FIG. 5 is a block diagram illustrating a wireless charging systemprovided by still another embodiment of the present disclosure.

FIG. 6 is a block diagram illustrating a device to be charged providedby an embodiment of the present disclosure.

FIG. 7 is a block diagram illustrating a device to be charged providedby another embodiment of the present disclosure.

FIG. 8 is a block diagram illustrating a wireless charging systemprovided by yet another embodiment of the present disclosure.

FIG. 9 is a flow chart of a wireless charging method provided by anembodiment of the present disclosure.

FIG. 10 is a flow chart of a wireless charging method provided byanother embodiment of the present disclosure.

FIG. 11 is a flow chart of a wireless charging method provided by yetanother embodiment of the present disclosure.

DETAILED DESCRIPTION

In embodiments of the present disclosure, a device to be charged ischarged based on a wireless charging technology, which can completepower transmission without a cable, simplifying operations in a chargingpreparation stage.

In the conventional wireless charging technology, a power supply device(for example, an adapter) is typically coupled with a wireless chargingdevice (for example, a wireless charging base), and an output power ofthe power supply device is transmitted to the device to be charged in awireless mode (for example, in a form of electromagnetic signal orelectromagnetic wave) from the wireless charging device, to performwireless charging on the device to be charged.

According to different wireless charging principles, the wirelesscharging mode can be implemented by magnetic coupling (orelectromagnetic induction), magnetic resonance, and radio waves. Atpresent, the mainstream wireless charging standards include a QIstandard, a PMA (power matters alliance) standard, and an A4WP (alliancefor wireless power). The QI standard and the PMA standard adopt themagnetic coupling for wireless charging. The A4WP standard adopts themagnetic resonance for wireless charging.

In the following, the conventional wireless charging mode is describedwith reference to FIG. 1 .

As illustrated in FIG. 1 , the wireless charging system includes a powersupply device 110, a wireless charging device 120 and a device to becharged 130. The wireless charging device 120 may be, for example, awireless charging base. The device to be charged 130 may be, forexample, a terminal.

After the power supply device 110 is coupled with the wireless chargingdevice 120, an output current of the power supply device 110 may betransmitted to the wireless charging device 120. The wireless chargingdevice 120 may convert the output current of the power supply device 110to an electromagnetic signal (or an electromagnetic wave) via aninternal wireless transmitter circuit 121 for transmitting. For example,the wireless transmitter circuit 121 may convert the output current ofthe power supply device 110 to alternating current, and convert thealternating current to the electromagnetic signal via a transmittingcoil or transmitting antenna (not shown).

The device to be charged 130 may receive the electromagnetic signaltransmitted by the wireless transmitter circuit 121 via a wirelessreceiver circuit 131, and convert the electromagnetic signal to anoutput current of the wireless receiver circuit 131. For example, thewireless receiver circuit 131 may convert the electromagnetic signaltransmitted by the wireless transmitter circuit 121 to alternatingcurrent via a receiving coil or receiving antenna (not shown), andperform operations such as rectification and/or filtering on thealternating current to convert the alternating current to an outputvoltage and an output current of the wireless receiver circuit 131.

For the conventional wireless charging technology, before the wirelesscharging, the wireless charging device 120 and the device to be charged130 may negotiate a transmitting power of the wireless transmittercircuit 121 in advance. Assuming that the power negotiated by thewireless charging device 120 and the device to be charged 130 is 5 W,the output voltage and the output current of the wireless receivercircuit 131 are generally 5V and 1 A. Assuming that the power negotiatedby the wireless charging device 120 and the device to be charged 130 is10.8 W, the output voltage and the output current of the wirelessreceiver circuit 131 are generally 9V and 1.2 A.

The output voltage of the wireless receiver circuit 131 is not suitablefor being directly applied to both ends of the battery 133, and needs tobe first converted by the conversion circuit 132 in the device to becharged 130, such that a charging voltage and/or a charging currentexpected by the battery 133 in the device to be charged 130 areobtained.

The conversion circuit 132 may be configured to convert the outputvoltage of the wireless receiver circuit 131, to meet a requirement ofthe charging voltage and/or charging current expected by the battery133.

As an example, the conversion circuit 132 may be a charging managementmodule, such as a charging integrated circuit (IC). During a chargingprocess of the battery 133, the conversion circuit 132 may be configuredto manage the charging voltage and/or charging current of the battery133. The conversion circuit 132 may have at least one of a voltagefeedback function and a current feedback function, so as to manage thecharging voltage and/or charging current of the battery 133.

For example, the charging process of the battery may include at leastone of a trickle charging stage, a constant current charging stage and aconstant voltage charging stage. In the trickle charging stage, theconversion circuit 132 may utilize a current feedback loop to ensurethat a current flowing into the battery 133 in the trickle chargingstage meets the charging current (such as a first charging current)expected by the battery 133. In the constant current charging stage, theconversion circuit 132 may utilize a current feedback loop to ensurethat the current flowing into the battery 133 in the constant currentcharging stage meets the charging current (such as a second chargingcurrent, which may be greater than the first charging current) expectedby the battery 133. In the constant voltage charging stage, theconversion circuit 132 may utilize a voltage feedback loop to ensurethat a voltage applied to both ends of the battery 133 in the constantvoltage charging stage meets the charging voltage expected by thebattery 133.

As an example, when the output voltage of the wireless receiver circuit131 is greater than the charging voltage expected by the battery 133,the conversion circuit 132 may be configured to perform a buckconversion on the output voltage of the wireless receiver circuit 131 toenable a buck-converted charging voltage to meet the requirement of thecharging voltage expected by the battery 133. As another example, whenthe output voltage of the wireless receiver circuit 131 is less than thecharging voltage expected by the battery 133, the conversion circuit 132may be configured to perform a boost conversion on the output voltage ofthe wireless receiver circuit 131 to enable a boost-converted chargingvoltage to meet the requirement of the charging voltage expected by thebattery 133.

As another example, assume that the wireless receiver circuit 131outputs a constant voltage of 5V. When the battery 133 includes a singlebattery cell (such as a lithium battery cell, a charging cut-off voltageof a single battery cell is typically 4.2V), the conversion circuit 132(for example, a buck circuit) may perform a buck conversion on theoutput voltage of the wireless receiver circuit 131, such that thecharging voltage obtained after the buck conversion meets a requirementof the charging voltage expected by the battery 133.

As yet another example, assume that the wireless receiver circuit 131outputs a constant voltage of 5V. When the battery 133 includes two ormore battery cells (such as lithium battery cell, a charging cut-offvoltage of a single battery cell is typically 4.2V) coupled in series,the conversion circuit 132 (for example, a boost circuit) may perform aboost conversion on the output voltage of the wireless receiver circuit131, such that the charging voltage obtained after the boost conversionmeets a requirement of the charging voltage expected by the battery 133.

Limited by a poor conversion efficiency of the conversion circuit 132, apart of electric energy is lost in a form of heat, and the heat maygather inside the device to be charged 130. A design space and a spacefor heat dissipation of the device to be charged are small (for example,the physical size of a mobile terminal used by a user becomes thinnerand thinner, while plenty of electronic elements are densely arranged inthe mobile terminal to improve performance of the mobile terminal),which not only increases difficulty in designing the conversion circuit132, but also results in that it is hard to dissipate the heat gatheredin the device to be charged 130 in time, thus further causing anabnormity of the device to be charged 130.

For example, the heat gathered on the conversion circuit 132 may cause athermal interference on electronic elements neighboring the conversioncircuit 132, thus causing abnormal operations of the electronicelements. For another example, the heat gathered on the conversioncircuit 132 may shorten the service life of the conversion circuit 132and neighboring electronic elements. For yet another example, the heatgathered on the conversion circuit 132 may cause a thermal interferenceon the battery 133, thus causing abnormal charging and/or abnormaldischarging of the battery 133. For still another example, the heatgathered on the conversion circuit 132 may increase the temperature ofthe device to be charged 130, thus affecting user experience during thecharging. For still yet another example, the heat gathered on theconversion circuit 132 may short-circuit the conversion circuit 132,such that the output voltage of the wireless receiver circuit 131 isdirectly applied to both ends of the battery 133, thus causing abnormalcharging of the battery 133, which brings safety hazard if theover-voltage charging lasts for a long time, for example, the battery133 may explode.

In order to solve above problems, embodiments of the present disclosureprovide a wireless charging system. In the wireless charging system, thewireless charging device can perform wireless communication with thedevice to be charged, and the transmitting power of the wirelesscharging device can be adjusted based on feedback information of thedevice to be charged, such that the output voltage and/or the outputcurrent of the wireless receiver circuit in the device to be charged canmatch a present charging stage of the battery. In other words, in thewireless charging system, the wireless charging device can performwireless communication with the device to be charged, and thetransmitting power of the wireless charging device can be adjusted basedon feedback information of the device to be charged, such that theoutput voltage and/or the output current of the wireless receivercircuit in the device to be charged can satisfy a present chargingrequirement of the battery (including a present requirement of thecharging voltage and/or the charging current of the battery). In thisway, in the device to be charged, the output voltage and/or the outputcurrent of the wireless receiver circuit can be directly applied to bothends of the battery, for charging the battery (hereinafter, thischarging mode is referred to as direct charging), thus avoiding theabove-mentioned problems such as energy loss and heating caused by theconversion circuit converting the output voltage and/or the outputcurrent of the wireless receiver circuit.

In the following, the wireless charging system 200 provided by anembodiment of the present disclosure is described in detail withreference to FIG. 2 .

As illustrated in FIG. 2 , the wireless charging system provided by anembodiment of the present disclosure may include a wireless chargingdevice 220 and a device to be charged 230.

The wireless charging device 220 may include a wireless transmittercircuit 221 and a first communication control circuit 222. Controlfunctions of the first communication control circuit 222 may beimplemented, for example, by a MCU (micro control unit).

The wireless transmitter circuit 221 may be configured to transmit anelectromagnetic signal to perform wireless charging on the device to becharged 230. In some embodiments, the wireless transmitter circuit 221may include a wireless transmission driver circuit and a transmittingcoil or transmitting antenna (not shown). The wireless transmissiondriver circuit may be configured to generate higher frequencyalternating current, and the transmitting coil or transmitting antennamay be configured to convert the higher frequency alternating current tothe electromagnetic signal and to transmit the electromagnetic signal.In one embodiment, the wireless transmission drive circuit includes aninverter circuit and a resonance circuit.

The first communication control circuit 222 is configured to performwireless communication with the device to be charged 230 during wirelesscharging to obtain a voltage and/or a current entering a battery of thedevice to be charged 230, for adjusting the transmitting power of thewireless transmitter circuit. Thus, by adjusting the transmitting powerof the wireless transmitter circuit, the voltage and/or current enteringthe battery can be adjusted. In one embodiment, adjusting the voltageand/or current entering the battery may include: causing an outputvoltage and/or an output current of the wireless receiver circuit in thedevice to be charged to match a present charging stage of the battery inthe device to be charged.

In detail, the first communication control circuit 222 may performwireless communication with a second communication control circuit 235in the device to be charged 230. In embodiments of the presentdisclosure, a wireless communication mode between the firstcommunication control circuit 222 and the second communication controlcircuit 235 and communication information between the firstcommunication control circuit 222 and the second communication controlcircuit 235 are not limited, and will be described in detail below withreference to specific embodiments.

The device to be charged 230 may include a wireless receiver circuit231, a battery 232, a first charging channel 233, a detection circuit234 and the second communication control circuit 235. Control functionsof the second communication control circuit 235 may be implemented, forexample, by a MCU (micro control unit), or may be implemented by the MCUtogether with an AP (application processor) in the device to be charged.

The detection circuit 234 is configured to detect the voltage and/orcurrent entering the battery 232 during wireless charging.

The second communication control circuit 235 is configured to performwireless communication with the wireless charging device 220 accordingto the voltage and/or current detected by the detection circuit, so thatthe wireless charging device 220 adjusts the transmitting power, therebyadjusting the voltage and/or current entering the battery 232.

In an embodiment, adjusting the voltage and/or current entering thebattery 232 may include: adjusting the transmitting power of thewireless transmitter circuit of the wireless charging device 220, suchthat an output voltage and/or an output current of the wireless receivercircuit of the device to be charged matches the present charging stageof the battery.

In an embodiment, the wireless receiver circuit 231 may be configured toreceive the electromagnetic signal, and to convert the electromagneticsignal to the output current and the output voltage of the wirelessreceiver circuit 231. In detail, the wireless receiver circuit 231 mayinclude a receiving coil or receiving antenna (not shown), and a shapingcircuit, such as a rectification circuit and/or a filtering circuit,coupled with the receiving coil or receiving antenna. The receiving coilor receiving antenna may be configured to convert the electromagneticsignal to alternating current. The shaping circuit may be configured toconvert the alternating current to the output voltage and the outputcurrent of the wireless receiver circuit 231. It should be noted that,in embodiments of the present disclosure, specific forms of the shapingcircuit and forms of the output current and the output voltage of thewireless receiver circuit 231 obtained after shaping of the shapingcircuit are not limited. In some embodiments, the shaping circuit mayinclude the rectification circuit and the filtering circuit, and theoutput voltage of the wireless receiver circuit 231 may be a stablevoltage obtained after filtering. In other embodiments, the shapingcircuit may include the rectification circuit, and the output voltage ofthe wireless receiver circuit 231 may be a voltage with a pulsatingwaveform obtained after rectification, in which the voltage with thepulsating waveform is directly applied to both ends of the battery 232in the device to be charged 230 for charging the battery 232. It couldbe understood that, the output current of the wireless receiver circuit231 may charge the battery 232 intermittently, and a period of theoutput current of the wireless receiver circuit 231 may vary with afrequency of the alternating current input into the wireless chargingsystem 200, for example, a frequency of an alternating current powergrid. For example, a frequency corresponding to the period of the outputcurrent of the wireless receiver circuit 231 may be an integral multipleor a reciprocal multiple of the frequency of the power grid. Moreover,when the output current of the wireless receiver circuit 231 may chargethe battery 232 intermittently, the current waveform corresponding tothe output current of the wireless receiver circuit 231 may consist ofone pulse or a set of pulses synchronous with the power grid. Amagnitude of the voltage/current with the pulsating waveform changesperiodically, which, compared to the conventional constant directcurrent, may reduce lithium precipitation of a lithium battery, andprolong a service life of the battery, and moreover may be beneficial toreduce polarization effect of the battery, improve a charging speed, andreduce heating of the battery, thus ensuring safety and reliability ofcharging the device to be charged.

The first charging channel 233 may be configured to receive the outputcurrent and the output voltage of the wireless receiver circuit 231, andto charge the battery 232 based on the output voltage and the outputcurrent of the wireless receiver circuit 231. The first charging channel233 provided by an embodiment of the present disclosure may performdirect charging on the battery 232 based on the output voltage and theoutput current of the wireless receiver circuit 231. For example, thefirst charging channel 233 may be a wire. For another example, when thedevice to be charged 230 includes a plurality of charging channels,elements such as a switch (referring to the switch 238 in FIG. 6 ) maybe provided on the first charging channel 233, for switching betweendifferent charging channels.

The detection circuit 234 may be configured to detect the output currentand/or the output voltage of the wireless receiver circuit 231. In someembodiments, the detection circuit 234 may include a voltage detectioncircuit and a current detection circuit.

The voltage detection circuit may be configured to sample the outputvoltage of the wireless receiver circuit 231, and to transmit thesampled voltage value to the second communication control circuit 235.In some embodiments, the voltage detection circuit may sample the outputvoltage of the wireless receiver circuit 231 by means of voltagedivision using a series circuit.

The current detection circuit may be configured to sample the outputcurrent of the wireless receiver circuit 231, and to transmit thesampled current value to the second communication control circuit 235.In some embodiments, the current detection circuit may sample the outputcurrent of the wireless receiver circuit 231 by means of a currentdetection resistor and a galvanometer.

The second communication control circuit 235 may be configured toperform wireless communication with the first communication controlcircuit 222 based on the output voltage and/or the output current of thewireless receiver circuit 231 detected by the detection circuit 234,such that the first communication control circuit 222 adjusts thetransmitting power of the wireless transmitter circuit 221, to enablethe output voltage and/or the output current of the wireless receivercircuit 231 to match the present charging stage of the battery 232.

In other words, the second communication control circuit 235 may beconfigured to perform wireless communication with the firstcommunication control circuit 222 based on the output voltage and/or theoutput current of the wireless receiver circuit 231 detected by thedetection circuit 234, such that the first communication control circuit222 adjusts the transmitting power of the wireless transmitter circuit221, to enable the output voltage and/or the output current of thewireless receiver circuit 231 to match a charging requirement of thebattery 232 (including a requirement of a charging voltage and/or acharging current of the battery 232).

In other words, the second communication control circuit 235 may beconfigured to perform wireless communication with the firstcommunication control circuit 222 based on the output voltage and/or theoutput current of the wireless receiver circuit 231 detected by thedetection circuit 234, such that the first communication control circuit222 adjusts the transmitting power of the wireless transmitter circuit221, to enable the output voltage and/or the output current of thewireless receiver circuit 231 to match a charging requirement of thebattery 232 in at least one stage of a trickle charging stage, aconstant voltage charging stage, and a constant current charging stage.

In other words, the second communication control circuit 235 may beconfigured to perform wireless communication with the firstcommunication control circuit 222 based on the output voltage and/or theoutput current of the wireless receiver circuit 231 detected by thedetection circuit 234, such that the first communication control circuit222 performs constant voltage and/or constant current control on acharging process of the battery 232 by adjusting the transmitting powerof the wireless transmitter circuit 221.

The charging process of the battery may include at least one of thetrickle charging stage, the constant current charging stage and theconstant voltage charging stage.

The second communication control circuit 235 may perform wirelesscommunication with the first communication control circuit 222 based onthe output voltage and/or the output current of the wireless receivercircuit 231 detected by the detection circuit 234, such that the firstcommunication control circuit 222 may adjust the transmitting power ofthe wireless transmitter circuit 221 according to the output voltageand/or the output current of the wireless receiver circuit 231 asfollows. During the trickle charging stage of the battery 232, thesecond communication control circuit 235 performs wireless communicationwith the first communication control circuit 222 based on the outputcurrent and/or the output voltage of the wireless receiver circuit 231detected by the detection circuit 234, such that the first communicationcontrol circuit 222 adjusts the transmitting power of the wirelesstransmitter circuit 221, to enable the output current of the wirelessreceiver circuit 231 to match a charging current corresponding to thetrickle charging stage (or, enable the output current of the wirelessreceiver circuit 231 to meet a requirement of the charging current ofthe battery 232 in the trickle charging stage).

Take the charging current corresponding to the trickle charging stagebeing 1 A as an example. When the battery 232 is in the trickle chargingstage, the output current of the wireless receiver circuit 231 may bedetected by the detection circuit 234 in real time. When the outputcurrent of the wireless receiver circuit 231 is greater than 1 A, thesecond communication control circuit 235 may communicate with the firstcommunication control circuit 222, such that the first communicationcontrol circuit 222 adjusts the transmitting power of the wirelesstransmitter circuit 221, to enable the output current of the wirelessreceiver circuit 231 to return to 1 A.

The second communication control circuit 235 may perform wirelesscommunication with the first communication control circuit 222 based onthe output voltage and/or the output current of the wireless receivercircuit 231 detected by the detection circuit 234, such that the firstcommunication control circuit 222 may adjust the transmitting power ofthe wireless transmitter circuit 221 according to the output voltageand/or the output current of the wireless receiver circuit 231 asfollows. During the constant voltage charging stage of the battery 232,the second communication control circuit 235 performs wirelesscommunication with the first communication control circuit 222 based onthe output voltage and/or the output current of the wireless receivercircuit 231 detected by the detection circuit 234, such that the firstcommunication control circuit 222 adjusts the transmitting power of thewireless transmitter circuit 221, to enable the output voltage of thewireless receiver circuit 231 to match a charging voltage correspondingto the constant voltage charging stage (or, enable the output voltage ofthe wireless receiver circuit 231 to meet a requirement of the chargingvoltage of the battery 232 in the constant voltage charging stage).

Take the charging voltage corresponding to the constant voltage chargingstage being 5V as an example. When the battery 232 is in the constantvoltage charging stage, the output voltage of the wireless receivercircuit 231 may be detected by the detection circuit in real time. Whenthe output voltage of the wireless receiver circuit 231 is less than 5V,the second communication control circuit 235 may communicate with thefirst communication control circuit 222, such that the firstcommunication control circuit 222 adjusts the transmitting power of thewireless transmitter circuit 221, to enable the output voltage of thewireless receiver circuit 231 to return back to 5V. There may be variousreasons resulting in change of the output voltage of the wirelessreceiver circuit 231, which will not be limited in embodiments of thepresent disclosure. For example, when transmission of theelectromagnetic signal between the wireless transmitter circuit 221 andthe wireless receiver circuit 231 is interfered, the energy conversionefficiency is reduced, thus resulting in that the output voltage of thewireless receiver circuit 231 is less than 5V.

The second communication control circuit 235 may perform wirelesscommunication with the first communication control circuit 222 based onthe output voltage and/or the output current of the wireless receivercircuit 231 detected by the detection circuit 234, such that the firstcommunication control circuit 222 may adjust the transmitting power ofthe wireless transmitter circuit 221 according to the output voltageand/or the output current of the wireless receiver circuit 231 asfollows. During the constant current charging stage of the battery 232,the second communication control circuit 235 performs wirelesscommunication with the first communication control circuit 222 based onthe output current and/or the output voltage of the wireless receivercircuit 231 detected by the detection circuit 234, such that the firstcommunication control circuit 222 adjusts the transmitting power of thewireless transmitter circuit 221, to enable the output current of thewireless receiver circuit 231 to match a charging current correspondingto the constant current charging stage (or, enable the output current ofthe wireless receiver circuit 231 to meet a requirement of the chargingcurrent of the battery 232 in the constant current charging stage).

Take the charging current corresponding to the constant current chargingstage being 2 A as an example. When the battery 232 is in the constantcurrent charging stage, the output current of the wireless receivercircuit 231 may be detected by the detection circuit in real time. Whenthe output current of the wireless receiver circuit 231 is less than 2A, the second communication control circuit 235 may communicate with thefirst communication control circuit 222, such that the firstcommunication control circuit 222 adjusts the transmitting power of thewireless transmitter circuit 221, to enable the output current of thewireless receiver circuit 231 to return back to 2 A. There may bevarious reasons resulting in change of the output current of thewireless receiver circuit 231, which will not be limited in embodimentsof the present disclosure. For example, when transmission of theelectromagnetic signal between the wireless transmitter circuit 221 andthe wireless receiver circuit 231 is interfered, the energy conversionefficiency is reduced, thus resulting in that the output current of thewireless receiver circuit 231 is less than 2 A.

It should be noted that, it is not necessary to keep the chargingcurrent completely constant during the constant current charging stageor the constant current stage involved in embodiments of the presentdisclosure. For example, it may refer to in general that, a peak valueor a mean value of the charging current keeps constant in a certain timeperiod. In practice, a multi-stage constant current mode is typicallyadopted for charging in the constant current charging stage.

The multi-stage constant current charging may include N constant currentstages, where N is an integer no less than 2. The first charging stageof the multi-stage constant current charging starts with a predeterminedcharging current. N constant current stages in the multi-stage constantcurrent charging are performed in sequence from the first charging stageto the (N−1)^(th) charging stage. After the constant current charging isswitched from one constant current stage to the next constant currentstage, the peak value or mean value of the current with the pulsatingwaveform may be decreased. When the battery voltage reaches a chargingstop voltage threshold, the constant current charging is switched fromthe present constant current stage to the next constant current stage.The current change between two adjacent constant current stages may begradual, or may be in a stepped skip manner.

The device to be charged used in embodiments of the present disclosuremay refer to the “terminal”. The “terminal” may include, but is notlimited to a device configured to receive/transmit communication signalsvia a wired connection (for example, public switched telephone network(PSTN), digital subscriber line (DSL) connection, digital cableconnection, direct cable connection and/or another dataconnection/network) and/or via a wireless interface (for example,cellular network, wireless local area network (WLAN), digital TV networksuch as digital video broadcasting handheld (DVB-H) network, satellitenetwork, an amplitude modulation-frequency modulation (AM-FM)broadcasting transmitter, and/or a wireless interface of anothercommunication terminal). The communication terminal configured tocommunicate via the wireless interface may be referred to as “wirelesscommunication terminal”, “wireless terminal” and/or “mobile terminal”.Examples of a mobile terminal include, but are not limited to asatellite phone or a cell phone, a terminal combining a cell radio phoneand a personal communication system (PCS) having capability of dataprocess, fax, and data communication, a personal digital assistant (PDA)including a radio phone, a pager, Internet/Intranet access, a webbrowser, a note pad & address book, a calendar and/or a globalpositioning system (GPS) receiver, and a common laptop and/or handheldreceiver, or other electronic devices including a radio phonetransceiver. In addition, the device to be charged or terminal used inembodiments of the present disclosure may further include a power bank.The power bank may receive charging from an adapter, and store theenergy, for providing power for other electronic devices.

The communication mode and the communication sequence between thewireless charging device 220 and the device to be charged 230 are notlimited in embodiments of the present disclosure.

Alternatively, in some embodiments, the wireless communication betweenthe wireless charging device 220 and the device to be charged 230 (or,between the second communication control circuit 235 and the firstcommunication control circuit 222) may be a unidirectional wirelesscommunication. For example, during the wireless charging of the battery232, the device to be charged 230 may be an initiator of thecommunication, and the wireless charging device 220 may be a receiver ofthe communication. For example, during the constant current chargingstage of the battery, the device to be charged 230 may detect thecharging current of the battery 232 (i.e., the output current of thewireless receiver circuit 231) in real time using the detection circuit234, and when the charging current of the battery 232 does not match thecharging stage in which the battery presently is, the device to becharged 230 sends an adjustment message to the wireless charging device220, to instruct the wireless charging device 220 to adjust thetransmitting power of the wireless transmitter circuit 221.

Alternatively, in some embodiments, the wireless communication betweenthe wireless charging device 220 and the device to be charged 230 (or,between the second communication control circuit 235 and the firstcommunication control circuit 222) may be a bidirectional wirelesscommunication. The bidirectional wireless communication generallyrequires that, the receiver sends a response message to the initiatorafter receiving the communication request initiated by the initiator.The bidirectional communication scheme may enable the communication tobe safer.

The master-slave relation of the wireless charging device 220 (the firstcommunication control circuit 222 in the wireless charging device 220)and the device to be charged 230 (the second communication controlcircuit 235 in the device to be charged 230) is not limited by abovedescription of embodiments of the present disclosure. In other words,any of the wireless charging device 220 and the device to be charged 230can be configured as the master device for initiating the bidirectionalcommunication session, accordingly, the other one can be configured asthe slave device for making a first response or a first reply to thecommunication initiated by the master device. As a feasibleimplementation, during the communication, the identities of the masterdevice and the slave device can be determined by comparing the linkstates between the wireless charging device 220 and the device to becharged 230. For example, assume that the wireless link of sendingmessages from the wireless charging device 220 to the device to becharged 230 is the uplink, and the wireless link of sending messagesfrom the device to be charged 230 to the wireless charging device is thedownlink. If the link quality of the uplink is better, the wirelesscharging device 220 may be configured as the master device of thecommunication. If the link quality of the downlink is better, the deviceto be charged 230 may be configured as the slave device of thecommunication.

The specific implementation of bidirectional communication between thewireless charging device 220 and the device to be charged 230 is notlimited in embodiments of the present disclosure. In other words, any ofthe wireless charging device 220 and the device to be charged 230 can beconfigured as the master device for initiating the bidirectionalcommunication session, accordingly, the other one can be configured asthe slave device making a first response or a first reply to thecommunication initiated by the master device, and the master device isable to make a second response to the first response or the first replyof the slave device, and thus one negotiation process is completedbetween the master device and the slave device.

As an implementation, the mater device is able to make a second responseto the first response or the first reply made by the slave device withrespect to the communication session in a manner that, the master deviceis able to receive the first response or the first reply made by theslave device with respect to the communication session and to make atargeted second response to the first response or the first reply.

As another implementation, the master device is able to make a secondresponse to the first response or the first reply made by the slavedevice with respect to the communication session in a manner that, whenthe master device does not receive the first response or the first replymade by the slave device with respect to the communication session inthe predetermined time period, the mater device also makes the targetedsecond response to the first response or the first reply of the slavedevice.

Alternatively, in some embodiments, when the device to be charged 230 isconfigured as the master device for initiating the communicationsession, after the wireless charging device 220 configured as the slavedevice makes the first response or the first reply to the communicationsession initiated by the master device, it is unnecessary for the deviceto be charged 230 to make the targeted second response to the firstresponse or the first reply of the wireless charging device 220, i.e.,one negotiation process is regarded as completed between the wirelesscharging device 220 and the device to be charged 230.

In embodiments of the present disclosure, the wireless communicationmode between the first communication control circuit 222 of the wirelesscharging device 220 and the second communication control circuit 235 ofthe device to be charged 230 is not limited. For example, the firstcommunication control circuit and the second communication controlcircuit may perform the wireless communication based on Bluetooth, Wi-Fi(wireless fidelity), short-range wireless communication based on highcarrier frequency, optical communication, ultrasonic communication,ultra-wideband communication, mobile communication, or backscattermodulation (or power load modulation).

In an embodiment, the first communication control circuit may includeany one or more of the following modules for performing wirelesscommunication with the second communication control circuit: a Bluetoothmodule, a Wi-Fi module, a short-range wireless communication modulebased on high carrier frequency, an optical communication module, anultrasonic communication module, an ultra-wideband communication module,and a mobile communication module.

In an embodiment, the short-range wireless communication module based onthe high carrier frequency includes an IC chip internally packaged withan EHF antenna. Alternatively, the high carrier frequency is 60 GHz.

In an embodiment, the optical communication module includes an infraredcommunication module that can transmit information using infrared rays.

In an embodiment, the mobile communication module can performinformation transmission using a mobile communication protocol such as a5G communication protocol, a 4G communication protocol, or a 3Gcommunication protocol.

Accordingly, the second communication control circuit 235 may includeany one or more of the following modules for performing wirelesscommunication with the first communication control circuit 222: aBluetooth module, a Wi-Fi module, a short-range wireless communicationmodule based on high carrier frequency, an optical communication module,an ultrasonic communication module, an ultra-wideband communicationmodule, and a mobile communication module.

Thus, the wireless communication between the first communication controlcircuit 222 and the second communication control circuit 235 includesany one or more of the following modes: Bluetooth communication, Wi-Ficommunication, short-range wireless communication based on a highcarrier frequency, optical communication, ultrasonic communication,ultra-wideband communication, and mobile communication.

In an embodiment of the present disclosure, the first communicationcontrol circuit 222 and the second communication control circuit 235 maysupport one or more wireless communication modes. In variousembodiments, the wireless communication may include standardcommunication or non-standard communication. Some examples of thestandard wireless communication include: link protocols including butnot limited to, Bluetooth, IEEE 802.11 (wireless LANs), 802.15 (WPANs),802.16 (WiMAX), 802.20 mobile wireless broadband access; cellularprotocols (mobile communication protocols), including but not limitedto, 5G standard protocols, LTE, CDMA, and GSM; and Zigbee and UltraWideband (UWB) technologies. This type of protocols support RFcommunication, and some also support infrared communication. Other formsof wireless communication, such as ultrasonic communication, opticalcommunication, short-range wireless communication based on high carrierfrequencies, and the like, can also be employed. It should be understoodthat the above-mentioned standards for wireless communication includeboth previous and existing standards. Future versions for thesestandards and future standards are also included, without departing fromthe scope of this disclosure.

In the embodiment of the present disclosure, the first communicationcontrol circuit 222 and the second communication control circuit 235 mayalso determine the wireless communication mode to be adopted accordingto the detected signal strengths of various wireless communicationmodes. For example, when Wi-Fi is used for wireless communication, if itis detected that the Wi-Fi signal is weak, it switches to anotherwireless communication mode.

With the wireless communication method of the embodiment of the presentdisclosure, information such as voltage, current or power entering thebattery is transmitted to the wireless charging device, so that thewireless charging device can adjust the transmitting power of thewireless transmitter circuit in real time according to the receivedinformation. With the above-described wireless communication method, thereliability of communication can be improved, thereby improving thecharging security. Compared with the method of coupling into the coil ofthe wireless receiver circuit by signal modulation in the related art(for example, Qi standard), the reliability of communication can beimproved, and the voltage ripple caused by signal coupling can beavoided, which avoids affecting the voltage processing process of theconversion circuit or the Buck circuit of the device to be charged.

As mentioned above, during the wireless charging, the secondcommunication control circuit 235 may perform the wireless communicationwith the first communication control circuit 222 based on the outputvoltage and/or the output current of the first charging channel detectedby the detection circuit 234, such that the first communication controlcircuit 222 adjusts the transmitting power of the wireless transmittercircuit 221. However, in embodiments of the present disclosure,communication content between the second communication control circuit235 and the first communication control circuit 222 is not limited. Asan example, the second communication control circuit 235 may send theoutput voltage and/or the output current of the wireless receivercircuit 231 detected by the detection circuit 234 to the firstcommunication control circuit 222. Further, the second communicationcontrol circuit 235 may further send battery status information to thefirst communication control circuit 222, in which the battery statusinformation includes a present electric quantity and/or a presentvoltage of the battery 232 in the device to be charged 230. The firstcommunication control circuit 222 may first determine the charging stagein which the battery 232 presently is according to the battery statusinformation, and further determine a target charging voltage and/or atarget charging current matching the charging stage in which the battery232 presently is. Next, the first communication control circuit 222 maycompare the output voltage and/or the output current of the wirelessreceiver circuit 231 sent from the second communication control circuit235 with the target charging voltage and/or the target charging current,to determine whether the output voltage and/or the output current of thewireless receiver circuit 231 match the charging stage in which thebattery 232 presently is. When the output voltage and/or the outputcurrent of the wireless receiver circuit 231 does not match the chargingstage in which the battery 232 presently is, the first communicationcontrol circuit 222 adjusts the transmitting power of the wirelesstransmitter circuit 221 until the output voltage and/or the outputcurrent of the wireless receiver circuit 231 match the charging stage inwhich the battery 232 presently is.

As another example, the second communication control circuit 235 maysend the adjustment message to the first communication control circuit222, to instruct the first communication control circuit 222 to adjustthe transmitting power of the wireless transmitter circuit 221. Forexample, the second communication control circuit 235 may instruct thefirst communication control circuit 222 to increase the transmittingpower of the wireless transmitter circuit 221. For another example, thesecond communication control circuit 235 may instruct the firstcommunication control circuit 222 to decrease the transmitting power ofthe wireless transmitter circuit 221. In more detail, the wirelesscharging device 220 may set a plurality of levels for the transmittingpower of the wireless transmitter circuit 221. Every time when the firstcommunication control circuit 222 receives the adjustment message, itadjusts the transmitting power of the wireless transmitter circuit 221by one level until the output voltage and/or the output current of thewireless receiver circuit 231 match the charging stage in which thebattery 232 presently is.

Besides the above communication contents, many other communicationinformation may be communicated between the first communication controlcircuit 222 and the second communication control circuit 235. In someembodiments, information used for safety protection, abnormalitydetection or failure processing, for example, temperature information ofthe battery 232, information indicating entering overvoltage protectionor overcurrent protection, and power transmission efficiency information(the power transmission efficiency information may be configured toindicate a power transmission efficiency between the wirelesstransmitter circuit 221 and the wireless receiver circuit 231), may becommunicated between the first communication control circuit 222 and thesecond communication control circuit 235.

For example, when the temperature of the battery 232 is too high, thefirst communication control circuit 222 and/or the second communicationcontrol circuit 235 may control the charging loop to enter a protectionstate, for example, control the charging loop to stop the wirelesscharging. For another example, after the first communication controlcircuit 222 receives the information indicating the overvoltageprotection or the overcurrent protection sent by the secondcommunication control circuit 235, the first communication controlcircuit 222 may reduce the transmitting power, or control the wirelesstransmitter circuit 221 to stop working. For another example, after thefirst communication control circuit 222 receives the power transmissionefficiency information sent by the second communication control circuit235, the first communication control circuit 222 may control thewireless transmitter circuit 221 to stop working if the powertransmission efficiency is lower than a preset threshold, and inform theuser of this matter, for example, may display via the display screenthat the power transmission efficiency is too low, or may indicate viaan indicator light that the power transmission efficiency is too low,such that the user may adjust the environment of the wireless charging.

In some embodiments, other information that can be used to adjust thetransmitting power of the wireless transmitter circuit 221, for example,the temperature information of the battery, the information indicating apeak value or a mean value of the output voltage and/or the outputcurrent of the wireless receiver circuit 231, and the power transmissionefficiency information (the power transmission efficiency informationmay be configured to indicate the power transmission efficiency betweenthe wireless transmitter circuit 221 and the wireless receiver circuit231), may be communicated between the first communication controlcircuit 222 and the second communication control circuit 235.

For example, the second communication control circuit 235 may send thepower transmission efficiency information to the first communicationcontrol circuit 222, and the first communication control circuit isfurther configured to determine an adjustment magnitude of thetransmitting power of the wireless transmitter circuit 221 according tothe power transmission efficiency information. In detail, if the powertransmission efficiency information indicates that the powertransmission efficiency between the wireless transmitter circuit 221 andthe wireless receiver circuit 231 is low, the first communicationcontrol circuit 222 may increase the adjustment magnitude of thetransmitting power of the wireless transmitter circuit 221, such thatthe transmitting power of the wireless transmitter circuit 221 may reachthe target power faster.

For another example, when the wireless receiver circuit 231 outputs thevoltage and/or the current with the pulsating waveform, the secondcommunication control circuit 235 may send the information indicatingthe peak value or the mean value of the output voltage and/or the outputcurrent of the wireless receiver circuit 231 to the first communicationcontrol circuit 222, and the first communication control circuit 222 maydetermine whether the peak value or the mean value of the output voltageand/or the output current of the wireless receiver circuit 231 matchesthe charging stage in which the battery presently is, and if not, mayadjust the transmitting power of the wireless transmitter circuit 221.

For another example, the second communication control circuit 235 maysend the temperature information of the battery 232 to the firstcommunication control circuit 222, and if the temperature of the battery232 is too high, the first communication control circuit 222 may reducethe transmitting power of the wireless transmitter circuit 221, toreduce the output current of the wireless receiver circuit 231, thusreducing the temperature of the battery 232.

As illustrated in FIG. 3 , the wireless charging device 220 provided byan embodiment of the present disclosure may further include a charginginterface 223. The wireless transmitter circuit 221 may be furtherconfigured to receive the output voltage and the output current of thepower supply device 210 via the charging interface 223, and to generatethe electromagnetic signal according to the output voltage and theoutput current of the power supply device 210.

In embodiments of the present disclosure, a type of the power supplydevice 210 is not limited. For example, the power supply device 210 maybe an adapter, a power bank, a computer, or the like.

In embodiments of the present disclosure, a type of the charginginterface 223 is not limited. Alternatively, in some embodiments, thecharging interface 223 may be a USB interface. The USB interface may be,for example, a USB 2.0 interface, a micro USB interface, or a USB TYPE-Cinterface. Alternatively, in other embodiments, the charging interface223 may also be a lightning interface, or any other kind of parallelinterface and/or serial interface that can be used for charging.

In embodiments of the present disclosure, a communication mode betweenthe first communication control circuit 222 and the power supply device210 is not limited. As an example, the first communication controlcircuit 222 may be coupled with the power supply device 210 via acommunication interface other than the charging interface, and maycommunicate with the power supply device 210 via the communicationinterface. As another example, the first communication control circuit222 may communicate with the power supply device 210 in a wireless mode.For example, the first communication control circuit may communicatewith the power supply device 210 via NFC (near field communication). Asyet another example, the first communication control circuit 222 maycommunicate with the power supply device 210 via the charging interface223, without the need of arranging an additional communication interfaceor other wireless communication modules, such that an implementation ofthe wireless charging device 220 may be simplified. For example, thecharging interface 223 is the USB interface, and the first communicationcontrol circuit 222 may communicate with the power supply device 210based on data wires (such as D+ and/or D− wire) of the USB interface.For another example, the charging interface 223 may be the USB interface(e.g., USB TYPE-C interface) supporting a PD (power delivery)communication protocol, and the first communication control circuit 222may communicate with the power supply device 210 based on the PDcommunication protocol.

It should be understood that, the power supply device 210 may be aconventional power supply device with the constant output power, or maybe a power supply device with an adjustable output power provided byembodiments of the present disclosure. A voltage feedback loop and acurrent feedback loop may be arranged inside the power supply devicewith the adjustable output power, such that it is possible to adjust theoutput voltage and/or the output current of the power supply deviceaccording to practical requirements (hereinafter, the power supplydevice 210 is illustrated as the power supply device with the adjustableoutput power). Further, the power supply device 210 may have thecommunication function, and the first communication control circuit 222may be further configured to communicate with the power supply device210 to negotiate the output power of the power supply device 210.

As noted above, in embodiments of the present disclosure, the wirelesscharging device 220 can adjust the transmitting power of the wirelesstransmitter circuit 221 constantly during the charging process, suchthat the output voltage and/or the output current of the wirelessreceiver circuit 231 match the charging stage in which the battery 232presently is. In embodiments of the present disclosure, the way ofadjusting the transmitting power of the wireless transmitter circuit isnot limited. For example, the first communication control circuit 222may communicate with the power supply device 210 to adjust the outputcurrent and/or the output voltage of the power supply device 210, so asto adjust the transmitting power of the wireless transmitter circuit221. As another example, the first communication control circuit 222 mayadjust a power quantity drawn by the wireless transmitter circuit 221from the maximum output power supplied by the power supply device 210,so as to adjust the transmitting power of the wireless transmittercircuit 221. In the following, the way of adjusting the transmittingpower of the wireless transmitter circuit 221 is described in detailwith reference to FIGS. 4 and 5 .

As illustrated in FIG. 4 , alternatively, in an embodiment, the firstcommunication control circuit 222 may communicate with the power supplydevice 210 to negotiate the maximum output power of the power supplydevice 210. During the process in which the wireless transmitter circuit221 performs the wireless charging on the device to be charged 230according to the maximum output power of the power supply device 210,the first communication control circuit 222 may adjust the powerquantity drawn by the wireless transmitter circuit 221 from the maximumoutput power, to adjust the transmitting power of the wirelesstransmitter circuit 221.

In embodiments of the present disclosure, the first communicationcontrol circuit 222 communicates with the power supply device 210 havingthe adjustable output power, to negotiate the maximum output power ofthe power supply device 210. After the negotiation, the power supplydevice 210 may provide the output voltage and the output current to thewireless charging device 220 according to the maximum output power.During the charging, the first communication control circuit 222 maydraw a certain power quantity from the maximum output power for wirelesscharging according to practical requirements. In other words, inembodiments of the present disclosure, adjusting the transmitting powerof the wireless transmitter circuit 221 is controlled by the firstcommunication control circuit 222, which may adjust the transmittingpower of the wireless transmitter circuit 221 immediately afterreceiving the feedback information of the device to be charged 230,having advantages of fast adjustment speed and high efficiency.

In embodiments of the present disclosure, the way in which the firstcommunication control circuit 222 adjusts the transmitting power of thewireless transmitter circuit 221 is not limited. For example, the poweradjustment circuit may be arranged inside the first communicationcontrol circuit 222, or inside the wireless transmitter circuit 221, orbetween the first communication control circuit 222 and the wirelesstransmitter circuit 221, and the power adjustment circuit may be coupledwith the transmitting coil or transmitting antenna, for adjusting thepower received by the transmitting coil or transmitting antenna. Thepower adjustment circuit may include, for example, a PWM (pulse widthmodulation) controller and a switch unit. The first communicationcontrol circuit 222 may adjust the transmitting power of the wirelesstransmitter circuit 221 by adjusting a duty ratio of a control signalsent by the PWM controller, and/or by controlling a switch frequency ofthe switch unit.

It should be noted that, in an embodiment as illustrated in FIG. 4 , asan alternative implementation, the power supply device 210 may have thefixed and higher output power (for example, 40 W). In this way, thefirst communication control circuit 222 may not need to negotiate withthe power supply device 210 about the maximum output power of the powersupply device 210, and may directly adjust the power quantity drawn bythe wireless transmitter circuit 221 from the fixed power supplied bythe power supply device 210.

As illustrated in FIG. 5 , alternatively, in other embodiments, thefirst communication control circuit 222 may communicate with the powersupply device 210 to adjust the output voltage and/or the output currentof the power supply device 210, so as to adjust the transmitting powerof the wireless transmitter circuit 221. Further, in some embodiments,the first communication control circuit 222 may be coupled with thewireless transmitter circuit 221, such that the first communicationcontrol circuit 222 may control the wireless transmitter circuit 221 tostart working, or control the wireless transmitter circuit 221 to stopworking when an abnormality occurs in the wireless charging.Alternatively, in some embodiments, the first communication controlcircuit 222 may be not coupled with the wireless transmitter circuit221.

In contrast to the embodiment in FIG. 4 , in the embodiment asillustrated in FIG. 5 , adjusting the transmitting power of the wirelesstransmitter circuit 221 is controlled by the power supply device 210,which adjusts the transmitting power of the wireless transmitter circuit221 by changing the output voltage and/or the output current. This wayof adjusting the transmitting power is advantageous in that, the powersupply device 210 may provide as much power as the wireless chargingdevice 220 needs, thus avoiding waste of power.

In the embodiment as illustrated in FIG. 5 , the wireless chargingdevice 220 may take the initiative to determine whether there is a needto adjust the output voltage and/or the output current of the powersupply device 210. In other embodiments, the wireless charging device220 may act as a bridge for communication between the power supplydevice 210 and the device to be charged 230, and is mainly responsiblefor forwarding information between the power supply device and thedevice to be charged 230.

For example, during the wireless charging, the first communicationcontrol circuit 222 communicates with the device to be charged 230, todetermine whether there is a need to adjust the output voltage and/orthe output current of the power supply device 210. When there is a needto adjust the output voltage and/or the output current of the powersupply device 210, the first communication control circuit 222communicates with the power supply device 210 to instruct the powersupply device 210 to adjust the output voltage and/or the output currentof the power supply device 210.

For another example, during the wireless charging, the communicationcontrol circuit 222 in the wireless charging device 220 performswireless communication with the device to be charged 230 to obtain theadjustment message, in which the adjustment message is configured toinstruct adjusting the output voltage and/or the output current of thepower supply device 210. The first communication control circuit 222communicates with the power supply device 210 to send the adjustmentmessage to the power supply device 210, such that the power supplydevice 210 adjusts the output voltage and/or the output current of thepower supply device according to the adjustment message.

It should be understood that, similar to the communication mode betweenthe wireless charging device 220 and the device to be charged 230, thecommunication between the wireless charging device 220 (or the firstcommunication control circuit 222) and the power supply device 210 maybe the unidirectional communication, or may be the bidirectionalcommunication, which is not limited in embodiments of the presentdisclosure.

It should also be understood that, the output current of the powersupply device may be constant direct current, pulsating direct currentor alternating current, which is not limited in embodiments of thepresent disclosure.

As described above, illustration is made in a case that the wirelesscharging device 220 is coupled with the power supply device 210 toobtain electric energy from the power supply device 210. However,embodiments of the present disclosure are not limited to this. Thefunction similar to the adapter may be integrated in the wirelesscharging device 220, such that the wireless charging device 220 maydirectly convert the alternating current input from the external (forexample, mains supply) to the electromagnetic signal. For example, thefunction of the adapter may be integrated in the wireless transmittercircuit 221 of the wireless charging device 220, for example, therectification circuit, the primary filtering circuit and/or thetransformer may be integrated in the wireless transmitter circuit 221.In this way, the wireless transmitter circuit 221 may be configured toreceive the alternating current input from the external (for example,220V alternating current, or the mains supply), and generate theelectromagnetic signal according to the alternating current.

In embodiments of the present disclosure, the function similar to theadapter is integrated in the wireless charging device 220, such that thewireless charging device 220 does not need to obtain power from theexternal power supply device, which improves the integration level ofthe wireless charging device 220, and reduces the number of devicesrequired for the wireless charging.

Alternatively, in some embodiments, the wireless charging device 220 maysupport a first wireless charging mode and a second wireless chargingmode, in which the maximum transmitting power of the wirelesstransmitter circuit in the first wireless charging mode is greater thanthe maximum transmitting power of the wireless transmitter circuit inthe second wireless charging mode. A charging speed of the wirelesscharging device 220 charging the device to be charged 230 in the firstwireless charging mode is greater than a charging speed of the wirelesscharging device 220 charging the device to be charged 230 in the secondwireless charging mode. In other words, compared to the wirelesscharging device 220 working in the second wireless charging mode, thewireless charging device 220 working in the first wireless charging modecan fully charge the battery having the same capacity in the device tobe charged 230 in a shorter time period.

The second wireless charging mode may be referred to as a normalwireless charging mode, which may be, for example, the conventionalwireless charging mode based on QI standard, PMA standard or A4WPstandard. The first wireless charging mode may be referred to as a fastwireless charging mode. The normal wireless charging mode may refer tothe wireless charging mode in which the transmitting power of thewireless charging device 220 is relatively lower (typically, less than15 W, and the commonly used transmitting power is 5 W or 10 W). In thenormal wireless charging mode, it may take several hours to fully chargea larger capacity battery (such as a battery with 3000 mAh). Incontrast, under the fast wireless charging mode, the transmitting powerof the wireless charging device 220 is relatively higher (typically,greater than or equal to 15 W). Compared to the normal wireless chargingmode, the charging speed of the wireless charging device 220 in the fastwireless charging mode is faster, and the charging time required forfully charging a battery with a same capacity in the fast wirelesscharging mode may be significantly shortened.

Alternatively, in some embodiments, the first communication controlcircuit 222 performs the bidirectional communication with the secondcommunication control circuit 235, to control the transmitting power ofthe wireless charging device 220 in the first wireless charging mode.

Further, in some embodiments, the first communication control circuit222 may perform the bidirectional communication with the secondcommunication control circuit 235 to control the transmitting power ofthe wireless charging device 220 in the first wireless charging mode asfollows. The first communication control circuit 222 performs thebidirectional communication with the second communication controlcircuit 235 to negotiate the wireless charging mode between the wirelesscharging device 220 and the device to be charged 230.

In detail, the first communication control circuit 222 may performhandshake communication with the second communication control circuit235, control the wireless charging device 220 to charge the device to becharged 230 in the first wireless charging mode when the handshakecommunication succeeds, and control the wireless charging device 220 tocharge the device to be charged 230 in the second wireless charging modewhen the handshake communication fails.

The handshake communication may refer to recognize the other's identityby any of the communication parties. When the handshake communicationsucceeds, it indicates that both the wireless charging device 220 andthe device to be charged 230 support the wireless charging mode withadjustable transmitting power provided by embodiments of the presentdisclosure. When the handshake communication fails, it indicates that atleast one of the wireless charging device 220 and the device to becharged 230 does not support the wireless charging mode with adjustabletransmitting power provided by embodiments of the present disclosure.

In embodiments of the present disclosure, the wireless charging device220 does not perform the fast wireless charging on the device to becharged 230 in the first wireless charging mode blindly, but performsthe bidirectional communication with the device to be charged 230 tonegotiate whether the wireless charging device 220 can perform the fastwireless charging on the device to be charged 230 in the first wirelesscharging mode. In this way, safety of charging process can be improved.

In detail, the first communication control circuit 222 performs thebidirectional communication with the second communication controlcircuit 235 to negotiate the wireless charging mode between the wirelesscharging device 220 and the device to be charged 230 as follows. Thefirst communication control circuit 222 sends a first instruction to thesecond communication control circuit 235, in which the first instructionis configured to query the device to be charged 230 whether to operatein the first wireless charging mode. The first communication controlcircuit 222 receives a reply instruction of the first instruction sentby the second communication control circuit 235, in which the replyinstruction of the first instruction is configured to indicate whetherthe device to be charged 230 agrees to operate in the first wirelesscharging mode. When the device to be charged 230 agrees to operate inthe first wireless charging mode, the first communication controlcircuit 222 controls the wireless charging device 220 to charge thedevice to be charged 230 in the first wireless charging mode.

Besides determining the wireless charging mode based on the negotiation,the first communication control circuit 222 may select or switch thewireless charging mode according to some other factors. For example, thefirst communication control circuit 222 may control the wirelesscharging device 220 to charge the battery 232 in the first wirelesscharging mode or in the second wireless charging mode according to thetemperature of the battery 232.

For example, when the temperature is less than a preset first threshold(for example, 5° C. or 10° C.), the first communication control circuit222 may control the wireless charging device 220 to perform the normalcharging in the second wireless charging mode; when the temperature isgreater than or equal to the first threshold, the first communicationcontrol circuit 222 may control the wireless charging device 220 toperform the fast charging in the first wireless charging mode. Further,when the temperature is greater than a high temperature threshold (forexample, 50° C.), the first communication control circuit 222 maycontrol the wireless charging device 220 to stop charging.

It should be noted that, the wireless charging mode with adjustabletransmitting power provided by embodiments of the present disclosure maybe used to control one or more of charging stages of the battery 232.For example, the wireless charging mode with adjustable transmittingpower provided by embodiments of the present disclosure may be mainlyused to control the constant current charging stage of the battery 232.In other embodiments, the device to be charged 230 may keep theconversion circuit. When the battery is in the trickle charging stageand the constant voltage charging stage, the conventional wirelesscharging mode as illustrated in FIG. 1 may be used for charging. Indetail, when the battery 232 is in the trickle charging stage and theconstant voltage charging stage, the conversion circuit in the device tobe charged 230 may convert the output voltage and the output current ofthe wireless receiver circuit 231, to make them satisfy the chargingrequirement of the trickle charging stage and the constant voltagecharging stage. Compared to the constant current charging stage, thecharging power received by the battery 232 in the trickle charging stageand the constant voltage charging stage is lower, and efficiency lossand heat accumulation of the conversion circuit in the device to becharged 230 are acceptable. Detailed description will be given belowwith reference to FIG. 6 .

As illustrated in FIG. 6 , the device to be charged 230 may furtherinclude a second charging channel 236. The conversion circuit 237 may bearranged on the second charging channel 236. The conversion circuit 237may be configured to receive the output current and the output voltageof the wireless receiver circuit 231, to convert the output currentand/or the output voltage of the wireless receiver circuit 231, and tocharge the battery 232 based on the converted current and/or theconverted voltage. The second communication control circuit 235 may befurther configured to control switch between the first charging channel233 and the second charging channel 236. For example, as illustrated inFIG. 6 , the first charging channel 233 may be provided with a switch238, and the second communication control circuit 235 may control theswitch between the first charging channel 233 and the second chargingchannel 236 by controlling the switch 238 to switch on and off.

For example, when the battery 232 is in the trickle charging stageand/or the constant voltage charging stage, the second communicationcontrol circuit 235 may control charging the battery 232 using thesecond charging channel 236, in which the constant voltage and constantcurrent process of the battery may be controlled by the conversioncircuit 237 (for example, a charging IC). When the battery 232 is in theconstant current charging stage, the second communication controlcircuit 235 may control charging the battery 232 using the firstcharging channel 233, in which the constant current control of thebattery may be implemented based on adjusting the transmitting power bythe wireless charging device. Keeping the conversion circuit 237 makesit possible to be better compatible with conventional wireless chargingmodes.

In an embodiment, the device to be charged further includes a step-downcircuit disposed on the first charging channel. The step-down circuit isconfigured to receive the output voltage of the wireless receivercircuit, and perform a step-down process on the output voltage of thewireless receiver circuit, for charging the battery. In an embodiment ofthe present disclosure, the implementation of the step-down circuit maybe various. As an example, the step-down circuit may be a Buck circuit.As another example, the step-down circuit may be a charge pump. Thecharge pump is composed of a plurality of switching elements. The heatgenerated by the current flowing through the switching element is verysmall, and is almost equivalent to the current directly passing throughthe wire. Therefore, the charge pump is used as the step-down circuit,which not only can reduce the voltage, but also reduce heat generation.As an example, the step-down circuit may also be a half voltage circuit.The ratio of the output voltage to the input voltage of the half voltagecircuit is fixed, thereby stabilizing the voltage difference of thestep-down circuit and reducing the heat generation of the step-downcircuit.

In an embodiment of the present disclosure, the output voltage and/orthe output current in the first charging channel may refer to a voltageand/or current between the wireless receiver circuit and the step-downcircuit, i.e., the output voltage and/or current of the wirelessreceiver circuit. Alternatively, the output voltage and/or the outputcurrent value in the first charging channel may also refer to a voltagevalue and/or a current value between the step-down circuit and thebattery, that is, the output voltage and/or the output current of thestep-down circuit, or the voltage and/or current entering the battery.In addition, if the first charging channel is not provided with astep-down circuit, the output voltage value and/or the output current inthe first charging channel may refer to the output voltage and/orcurrent of the wireless receiver circuit, or the voltage and/or currententering the battery.

Compared with the related art, the above wireless communication methodperformed by the wireless charging device and the device to be chargedin the embodiment of the present disclosure does not require thetransmitting coil and the receiving coil for charging to perform thecommunication task, thereby eliminating the ripple problem of the outputvoltage caused by the coil communication. For the voltage ripple outputfrom the wireless receiving coil, if the ripple is not processed, it maycause charging safety problems. Through the embodiment of the presentdisclosure, the voltage ripple may be eliminated, thereby eliminatingthe circuit for processing the ripple, reducing the complexity of thecharging circuit of the device to be charged, improving the chargingefficiency, and saving the circuit setting space. When the battery ischarged by using the first charging channel, the first charging channelmay be only provided with the step-down circuit. Moreover, since thedevice to be charged feed back the information concerning the voltage,current or power entering the battery to the wireless charging device inreal time, the wireless charging device can adjust the transmittingpower in real time, and since the effect of the voltage ripple iseliminated, the step-down circuit may be configured as the half voltagecircuit, thereby further reducing the complexity of the circuit, beingbeneficial to control the temperature rise, and improving the chargingefficiency.

It should be noted that, there are various ways for selecting betweenthe first charging channel 233 and the second charging channel 236,which is not limited to selection based on the charging stage in whichthe battery 232 presently is.

Alternatively, in some embodiments, the second communication controlcircuit 235 may be further configured to perform handshake communicationwith the first communication control circuit 222, to control the firstcharging channel 233 to work when the handshake communication succeeds,and to control the second charging channel 236 to work when thehandshake communication fails.

The handshake communication may refer to recognize the other's identityby any of the communication parties. When the handshake communicationsucceeds, it indicates that both the wireless charging device 220 andthe device to be charged 230 support the wireless charging mode withadjustable transmitting power provided by embodiments of the presentdisclosure. When the handshake communication fails, it indicates that atleast one of the wireless charging device 220 and the device to becharged 230 does not support the wireless charging mode with adjustabletransmitting power provided by embodiments of the present disclosure. Ina case that the handshake communication fails, the charging may beperformed via the second charging channel 236 by the conventionalwireless charging mode, such as the wireless charging mode based on QIstandard.

Alternatively, in other embodiments, the second communication controlcircuit 235 may be further configured to control the switch between thefirst charging channel 233 and the second charging channel 236 accordingto the temperature of the battery 232.

For example, when the temperature is less than a preset first threshold(for example, 5° C. or 10° C.), the second communication control circuit235 may control performing the normal wireless charging via the secondcharging channel 236; when the temperature is greater than or equal tothe first threshold, the second communication control circuit 235 maycontrol performing the fast wireless charging via the first chargingchannel 233. Further, when the temperature is greater than a hightemperature threshold (for example, 50° C.), the second communicationcontrol circuit 235 may control stopping the wireless charging.

As noted above, the output current of the wireless receiver circuit 231may be pulsating direct current, which may reduce the lithiumprecipitation of the battery 232, and improve the service life of thebattery. When the wireless receiver circuit 231 outputs the pulsatingdirect current, the peak value or the mean value of the pulsating directcurrent may be detected by the detection circuit 234, such that thesecond communication control circuit 235 may perform subsequentcommunication or control based on the peak value or mean value of thepulsating direct current.

Take the detection circuit 234 detecting the peak value of the pulsatingdirect current as an example. As illustrated in FIG. 7 , the detectioncircuit 234 may include a sampling and holding circuit 2341. When thesampling and holding circuit 2341 is in a sampling state, the samplingand holding circuit 2341 is configured to sample the pulsating directcurrent. When the sampling and holding circuit 2341 is in a holdingstage, the sampling and holding circuit 2341 is configured to hold thepeak current value of the pulsating direct current. The secondcommunication control circuit 235 is further configured to determinewhether the sampling and holding circuit 2341 is in the holding state,and to sample the peak current value of the pulsating direct currentheld by the sampling and holding circuit 2341 when determining that thesampling and holding circuit 2341 is in the holding state.

Alternatively, in some embodiments, the sampling and holding circuit2341 may include a capacitor, and the sampling and holding circuit 2341may hold the peak current value of the pulsating direct current based onthe capacitor in the sampling and holding circuit 2341. The detectioncircuit 234 may further include a discharging circuit 2342. The secondcommunication control circuit 235 may release charges across both endsof the capacitor in the sampling and holding circuit via the dischargingcircuit 2342, such that the sampling and holding circuit switches to thesampling state from the holding state.

Alternatively, in some embodiments, the wireless charging device 220 mayfurther include a peripheral interface and a wireless data transmissioncircuit. The peripheral interface may be configured to be coupled withan electronic device having functions of data processing andtransmission. The peripheral interface may be the charging interfacedescribed above, or may be other interfaces. The first communicationcontrol circuit 222 may be further configured to perform the wirelesscharging on the device to be charged 230 according to the output powerof the electronic device when the peripheral interface is coupled withthe electronic device having functions of data processing andtransmission. The wireless data transmission circuit may be configuredto transmit data stored in the electronic device to the device to becharged 230 via a wireless link, or transmit data stored in the deviceto be charged 230 to the electronic device via a wireless link, duringthe process in which the wireless charging control unit performs thewireless charging on the device to be charged 230 according to theoutput power of the electronic device. The wireless data transmissioncircuit may be configured to transmit at least one of data in a USBprotocol format, data in a DP (display port) protocol format, and datain a MHL (mobile high-definition link) format.

Embodiments of the present disclosure are described in more detail belowin combination with specific examples. In FIG. 8 , the wireless chargingdevice is illustrated as a wireless charging base, the power supplydevice is illustrated as an adapter, and the device to be charged isillustrated as a mobile phone. It should be noted that, the example inFIG. 8 is merely illustrated for helping those skilled in the art tounderstand embodiments of the present disclosure, and is not intended tolimit embodiments of the present disclosure to specific values orspecific scenario as illustrated. Those skilled in the art may performvarious equivalent modification or change based on the example in FIG. 8, which fall in the scope of the present disclosure.

At step 1, the mobile phone performs wireless communication with thewireless charging base.

In detail, the communication protocol of the bidirectional communicationbetween the mobile phone and the wireless charging base may be definedby manufacturers. In addition, the mobile phone and the wirelesscharging base may communicate with each other via Bluetooth, WiFi, orbackscatter modulation.

At step 2, the wireless charging base performs the wired bidirectionalcommunication with the adapter.

In detail, the communication protocol of the bidirectional communicationbetween the adapter and the wireless charging base may be defined bymanufacturers. In addition, the wireless charging base and the adaptermay communicate with each other via the USB wire (for example, via theD+ and D− data wire in the USB wire).

At step 3, the wireless charging base is coupled with the adapter, andperforms handshake communication with the adapter.

In detail, after being coupled with the adapter, the wireless chargingbase may performs handshake communication with the adapter, to determinethe type of the adapter and the power level that can be provided by theadapter.

At step 4, the wireless charging base is coupled with the mobile phone,and performs handshake communication with the mobile phone.

In detail, after being coupled with the mobile phone, the wirelesscharging base may perform handshake communication with the mobile phone,to determine the type of the mobile phone and the power level that canbe supported by the mobile phone.

At step 5, when the handshake between the wireless charging base and themobile phone and the handshake between the wireless charging base andthe adapter succeed, the wireless charging is activated.

The wireless receiver circuit in the mobile phone may perform directcharging on the battery. In order to be able to adjust the outputcurrent or the output voltage of the wireless receiver circuit in realtime according to the charging stage in which the battery presently is,the communication control circuit in the mobile phone may keepcommunication with the wireless charging base during the wirelesscharging, to instruct the wireless charging base to adjust thetransmitting power of the wireless transmitter circuit in real time. Forexample, the communication control circuit in the mobile phone mayobtain the present state of the battery in real time, and send theadjustment message to the wireless charging device based on the presentstate of the battery, in which the adjustment message is used foradjusting the output voltage or the output current of the adapter. Afterreceiving the adjustment message, the wireless charging device mayperform the bidirectional communication with the adapter, to instructthe adapter to adjust its output voltage and/or output current.

It should be noted that, when the wireless charging base fails to shakehands with any of the mobile phone and the adapter, the wirelesscharging base may perform the charging in the conventional wirelesscharging mode. For example, the wireless charging base may perform thewireless charging on the device to be charged with the power of 5 Wbased on the QI standard (5 W is corresponding to a low power level inthe QI standard).

In an embodiment of the present disclosure, the wireless transmittercircuit includes an inverter circuit and a resonance circuit. Theinverter circuit may include a plurality of switching tubes, and theoutput power can be adjusted by controlling the conduction time (dutyratio) of the switching tubes. The resonance circuit is configured totransmit the electrical energy. For example, the resonance circuit mayinclude a capacitor and a transmitting coil. By adjusting the resonancefrequency of the resonance circuit, the output power of the wirelesstransmitter circuit can be adjusted.

In an embodiment of the present disclosure, the wireless charging devicefurther includes a voltage conversion circuit. The voltage conversioncircuit is configured to receive an input voltage provided by the powersupply device, and convert the input voltage to obtain an output voltageand an output current of the voltage conversion circuit. The wirelesstransmitter circuit is configured to transmit an electromagnetic signalaccording to the output voltage and the output current of the voltageconversion circuit. For example, the voltage conversion circuit may be aBoost circuit or a Buck circuit.

In an embodiment, the first communication control circuit is configuredto adjust the output voltage and/or the output current of the voltageconversion circuit, so as to adjust the transmitting power of thewireless transmitter circuit.

In an embodiment, the first communication control circuit is configuredto adjust the duty ratio of the inverter circuit and/or adjust theresonance frequency of the resonance circuit, so as to adjust thetransmitting power of the wireless transmitter circuit. In an embodimentof the present disclosure, the battery of the device to be charged mayinclude a single cell or a plurality of cells. When the battery includesa plurality of cells, the plurality of cells are in series relationship.Therefore, the charging voltage that the battery can withstand is thesum of the charging voltages that can be withstood by the plurality ofcells, which can increase the charging speed and reduce the heatgenerated in the charging.

Taking the device to be charged as a mobile phone as an example, whenthe battery of the device to be charged includes a single battery cell,the voltage of the internal single-cell battery is generally between3.0V and 4.35V. When the battery of the device to be charged includestwo cells in series, the total voltage of the two cells in series is6.0V to 8.7V. Thereby, compared to the single cell, the output voltageof the wireless receiver circuit may be increased when the plurality ofcells are connected in series. Compared with the single cell, to achievethe same charging speed, the charging current required for the pluralityof cells is about 1/N of the charging current required for the singlecell (N is the number of the cells in series in the device to becharged). In other words, under the premise of ensuring the samecharging speed (the same charging power), the plurality of cells inseries can reduce the charging current, thereby reducing the heatgeneration of the device to be charged during the charging process. Onthe other hand, compared with the single cell, under the premise ofensuring the same charging current, the plurality of cells in series canbe used to increase the charging voltage and increase the chargingspeed.

Hereinbefore, device embodiments of the present disclosure are describedin detail with reference to FIGS. 2-8 . Hereinafter, method embodimentsof the present disclosure will be described in detail with reference toFIGS. 9-11 . The method embodiments are corresponding to the deviceembodiments, and thus with respect to parts that are not described indetail, reference may be made to above device embodiments.

Accordingly, a wireless charging method is provided by embodiments ofthe present disclosure. The wireless charging method is applicable to awireless charging device. The method includes:

performing wireless communication with the device to be charged duringwireless charging of the device to be charged.

The wireless communication includes any one or more of Bluetoothcommunication, Wi-Fi communication, short-range wireless communicationbased on a high carrier frequency, optical communication, ultrasoniccommunication, ultra-wideband communication and mobile communication.

Accordingly, a wireless charging method is further provided byembodiments of the present disclosure. The wireless charging method isapplicable to a device to be charged. The method includes:

performing wireless communication with a wireless charging device duringwireless charging of the battery. The wireless communication includesany one or more of Bluetooth communication, Wi-Fi communication,short-range wireless communication based on a high carrier frequency,optical communication, ultrasonic communication, ultra-widebandcommunication and mobile communication.

FIG. 9 is a flow chart of a wireless charging method according to anembodiment of the present disclosure. The method in FIG. 9 may beexecuted by a wireless charging system (for example, the wirelesscharging system 200 described above). The wireless charging systemincludes a wireless charging device and a device to be charged.

The wireless charging device includes a wireless transmitter circuit.The wireless transmitter circuit is configured to transmit anelectromagnetic signal to perform wireless charging on the device to becharged.

The device to be charged includes: a battery; a wireless receivercircuit, configured to receive the electromagnetic signal, and toconvert the electromagnetic signal to an output voltage and an outputcurrent of the wireless receiver circuit; a first charging channel,configured to receive the output voltage and the output current of thewireless receiver circuit, and to charge the battery based on the outputvoltage and the output current of the wireless receiver circuit; and adetection circuit, configured to detect the output voltage and/or theoutput current of the wireless receiver circuit.

The method in FIG. 9 includes, at 910, the device to be chargedperforming wireless communication with the wireless charging devicebased on the output current and/or the output voltage of the wirelessreceiver circuit detected by the detection circuit, such that thewireless charging device adjusts a transmitting power of the wirelesstransmitter circuit, to enable the output voltage and/or the outputcurrent of the wireless receiver circuit to match a charging stage inwhich the battery presently is.

Alternatively, in some embodiments, the wireless charging device furtherincludes a charging interface, and the wireless transmitter circuit isfurther configured to receive an output voltage and an output current ofa power supply device via the charging interface, and to generate theelectromagnetic signal according to the output voltage and the outputcurrent of the power supply device.

Alternatively, in some embodiments, the method in FIG. 9 may furtherinclude: the wireless charging device communicating with the powersupply device to negotiate an output power of the power supply device.

Alternatively, in some embodiments, the wireless charging devicecommunicating with the power supply device to negotiate the output powerof the power supply device may include: the wireless charging devicecommunicating with the power supply device to negotiate a maximum outputpower of the power supply device; and the wireless charging deviceadjusting the transmitting power of the wireless transmitter circuit mayinclude: during the wireless transmitter circuit performing wirelesscharging on the device to be charged according to the maximum outputpower of the power supply device, adjusting a power quantity drawn bythe wireless transmitter circuit from the maximum output power to adjustthe transmitting power of the wireless transmitter circuit.

Alternatively, in some embodiments, the wireless charging deviceadjusting the transmitting power of the wireless transmitter circuit mayinclude: the wireless charging device communicating with the powersupply device to adjust the output voltage and/or the output current ofthe power supply device, so as to adjust the transmitting power of thewireless transmitter circuit.

Alternatively, in some embodiments, the device to be charged performingwireless communication with the wireless charging device based on theoutput voltage and/or the output current of the wireless receivercircuit detected by the detection circuit, such that the wirelesscharging device adjusts the transmitting power of the wirelesstransmitter circuit, may include: the device to be charged sending anadjustment message to the wireless charging device, the adjustmentmessage being configured to instruct the wireless charging device toadjust the output voltage and/or the output current of the power supplydevice.

Alternatively, in some embodiments, the charging stage in which thebattery presently is includes at least one of a trickle charging stage,a constant voltage charging stage, and a constant current chargingstage.

Alternatively, in some embodiments, the device to be charged performingwireless communication with the wireless charging device based on theoutput current and/or the output voltage of the wireless receivercircuit detected by the detection circuit, such that the wirelesscharging device adjusts the transmitting power of the wirelesstransmitter circuit according to the output voltage and/or the outputcurrent of the wireless receiver circuit, may include: during theconstant voltage charging stage of the battery, the device to be chargedperforming wireless communication with the wireless charging devicebased on the output voltage and/or the output current of the wirelessreceiver circuit detected by the detection circuit, such that thewireless charging device adjusts the transmitting power of the wirelesstransmitter circuit, to enable the output voltage of the wirelessreceiver circuit to match a charging voltage corresponding to theconstant voltage charging stage.

Alternatively, in some embodiments, the device to be charged performingwireless communication with the wireless charging device based on theoutput current and/or the output voltage of the wireless receivercircuit detected by the detection circuit, such that the wirelesscharging device adjusts the transmitting power of the wirelesstransmitter circuit according to the output voltage and/or the outputcurrent of the wireless receiver circuit, may include: during theconstant current charging stage of the battery, the device to be chargedperforming wireless communication with the wireless charging devicebased on the output voltage and/or the output current of the wirelessreceiver circuit detected by the detection circuit, such that thewireless charging device adjusts the transmitting power of the wirelesstransmitter circuit, to enable the output current of the wirelessreceiver circuit to match a charging current corresponding to theconstant current charging stage.

Alternatively, in some embodiments, the method in FIG. 9 may furtherinclude: the device to be charged sending battery status information tothe wireless charging device, such that the wireless charging deviceadjusts the transmitting power of the wireless transmitter circuitaccording to the battery status information, in which the battery statusinformation includes a present electric quantity and/or a presentvoltage of the battery in the device to be charged.

Alternatively, in some embodiments, communication information betweenthe wireless charging device and the device to be charged includes atleast one of: temperature information of the battery; informationindicating a peak value or a mean value of the output current and/or theoutput voltage of the wireless receiver circuit; information indicatingentering overvoltage protection or overcurrent protection; and powertransmission efficiency information configured to indicate a powertransmission efficiency between the wireless transmitter circuit and thewireless receiver circuit.

Alternatively, in some embodiments, the communication informationincludes the power transmission efficiency information, and the methodin FIG. 9 may further include: the wireless charging device determiningan adjustment magnitude of the transmitting power of the wirelesstransmitter circuit according to the power transmission efficiencyinformation.

Alternatively, in some embodiments, the device to be charged furtherincludes a second charging channel provided with a conversion circuit,in which the conversion circuit is configured to receive the outputcurrent of the wireless receiver circuit, to convert the output currentof the wireless receiver circuit, and to charge the battery based onconverted current. The method in FIG. 9 may further include: the deviceto be charged controlling switch between the first charging channel andthe second charging channel.

Alternatively, in some embodiments, the method in FIG. 9 may furtherinclude: the device to be charged performing handshake communicationwith the wireless charging device, controlling the first chargingchannel to work when the handshake communication succeeds, andcontrolling the second charging channel to work when the handshakecommunication fails.

Alternatively, in some embodiments, the method in FIG. 9 may furtherinclude: the device to be charged controlling switch between the firstcharging channel and the second charging channel according to thetemperature of the battery.

Alternatively, in some embodiments, the wireless charging devicesupports a first wireless charging mode and a second wireless chargingmode, in which a charging speed of the wireless charging device chargingthe device to be charged in the first wireless charging mode is greaterthan a charging speed of the wireless charging device charging thedevice to be charged in the second wireless charging mode.

Alternatively, in some embodiments, the method in FIG. 9 may furtherinclude: the wireless charging device communicating with the device tobe charged to negotiate performing the wireless charging in the firstwireless charging mode or in the second wireless charging mode.

Alternatively, in some embodiments, the wireless charging devicecommunicating with the device to be charged to negotiate performing thewireless charging in the first wireless charging mode or in the secondwireless charging mode may include: the wireless charging deviceperforming handshake communication with the device to be charged,controlling the wireless charging device to charge the device to becharged in the first wireless charging mode when the handshakecommunication succeeds, and controlling the wireless charging device tocharge the device to be charged in the second wireless charging modewhen the handshake communication fails.

Alternatively, in some embodiments, the method in FIG. 9 may furtherinclude: the wireless charging device controlling the wireless chargingdevice to charge the battery in the first wireless charging mode or inthe second wireless charging mode according to the temperature of thebattery.

FIG. 10 is a flow chart of a wireless charging method according toanother embodiment of the present disclosure. The method in FIG. 10 maybe executed by a wireless charging device (for example, the wirelesscharging device 220 described above). The wireless charging deviceincludes a wireless transmitter circuit. The wireless transmittercircuit is configured to transmit an electromagnetic signal to perform awireless charging on a device to be charged.

The method in FIG. 10 includes, at 1010, during the wireless charging,performing wireless communication with the device to be charged toadjust a transmitting power of the wireless transmitter circuit, suchthat an output voltage and/or an output current of a wireless receivercircuit in the device to be charged match a charging stage in which abattery of the device to be charged presently is.

The wireless communication includes any one or more of Bluetoothcommunication, Wi-Fi communication, short-range wireless communicationbased on a high carrier frequency, optical communication, ultrasoniccommunication, ultra-wideband communication and mobile communication.

Alternatively, in some embodiments, the wireless charging device furtherincludes a charging interface, and the wireless transmitter circuit isfurther configured to receive an output voltage and an output current ofa power supply device via the charging interface, and to generate theelectromagnetic signal according to the output voltage and the outputcurrent of the power supply device.

Alternatively, in some embodiments, the method in FIG. 10 may furtherinclude: communicating with the power supply device to negotiate anoutput power of the power supply device.

Alternatively, in some embodiments, communicating with the power supplydevice to negotiate the output power of the power supply device mayinclude: communicating with the power supply device to negotiate amaximum output power of the power supply device; and adjusting thetransmitting power of the wireless transmitter circuit may include:during the wireless transmitter circuit performing wireless charging onthe device to be charged according to the maximum output power of thepower supply device, adjusting a power quantity drawn by the wirelesstransmitter circuit from the maximum output power to adjust thetransmitting power of the wireless transmitter circuit.

Alternatively, in some embodiments, adjusting the transmitting power ofthe wireless transmitter circuit may include: communicating with thepower supply device to adjust the output voltage and/or the outputcurrent of the power supply device, so as to adjust the transmittingpower of the wireless transmitter circuit.

Alternatively, in some embodiments, performing wireless communicationwith the device to be charged during the wireless charging to adjust thetransmitting power of the wireless transmitter circuit may include:receiving an adjustment message sent by the device to be charged, theadjustment message being configured to instruct the wireless chargingdevice to adjust the output voltage and/or the output current of thepower supply device.

Alternatively, in some embodiments, the charging stage in which thebattery presently is includes at least one of a trickle charging stage,a constant voltage charging stage, and a constant current chargingstage.

Alternatively, in some embodiments, performing wireless communicationwith the device to be charged during the wireless charging to adjust thetransmitting power of the wireless transmitter circuit, such that theoutput voltage and/or the output current of the wireless receivercircuit in the device to be charged match the charging stage in whichthe battery presently is, may include: during the constant voltagecharging stage of the battery, performing wireless communication withthe device to be charged to adjust the transmitting power of thewireless transmitter circuit, such that the output voltage of thewireless receiver circuit matches a charging voltage corresponding tothe constant voltage charging stage.

Alternatively, in some embodiments, performing wireless communicationwith the device to be charged during the wireless charging to adjust thetransmitting power of the wireless transmitter circuit, such that theoutput voltage and/or the output current of the wireless receivercircuit in the device to be charged match the charging stage in whichthe battery presently is, may include: during the constant currentcharging stage of the battery, performing wireless communication withthe device to be charged to adjust the transmitting power of thewireless transmitter circuit, such that the output current of thewireless receiver circuit matches a charging current corresponding tothe constant current charging stage.

Alternatively, in some embodiments, the method in FIG. 10 may furtherinclude: receiving battery status information sent by the device to becharged, and adjusting the transmitting power of the wirelesstransmitter circuit according to the battery status information, inwhich the battery status information includes a present electricquantity and/or a present voltage of the battery.

Alternatively, in some embodiments, communication information betweenthe wireless charging device and the device to be charged includes atleast one of: temperature information of the battery; informationindicating a peak value or a mean value of the output current and/or theoutput voltage of the wireless receiver circuit; information indicatingentering overvoltage protection or overcurrent protection; and powertransmission efficiency information configured to indicate a powertransmission efficiency between the wireless transmitter circuit and thewireless receiver circuit.

Alternatively, in some embodiments, the communication informationincludes the power transmission efficiency information, and the methodin FIG. 10 may further include: determining an adjustment magnitude ofthe transmitting power of the wireless transmitter circuit according tothe power transmission efficiency information.

Alternatively, in some embodiments, the wireless charging devicesupports a first wireless charging mode and a second wireless chargingmode, in which a charging speed of the wireless charging device chargingthe device to be charged in the first wireless charging mode is greaterthan a charging speed of the wireless charging device charging thedevice to be charged in the second wireless charging mode.

Alternatively, in some embodiments, the method in FIG. 10 may furtherinclude: communicating with the device to be charged to negotiateperforming the wireless charging in the first wireless charging mode orin the second wireless charging mode.

Alternatively, in some embodiments, communicating with the device to becharged to negotiate performing the wireless charging in the firstwireless charging mode or in the second wireless charging mode mayinclude: performing handshake communication with the device to becharged, controlling the wireless charging device to charge the deviceto be charged in the first wireless charging mode when the handshakecommunication succeeds, and controlling the wireless charging device tocharge the device to be charged in the second wireless charging modewhen the handshake communication fails.

Alternatively, in some embodiments, the method in FIG. 10 may furtherincludes: controlling the wireless charging device to charge the batteryin the first wireless charging mode or in the second wireless chargingmode according to the temperature of the battery.

FIG. 11 is a flow chart of a wireless charging method according to yetanother embodiment of the present disclosure. The method in FIG. 11 maybe executed by a device to be charged (for example, the device to becharged 230 described above). The device to be charged includes: abattery; a wireless receiver circuit, configured to receive anelectromagnetic signal transmitted by a wireless charging device, and toconvert the electromagnetic signal to an output current and an outputvoltage of the wireless receiver circuit; a first charging channel,configured to receive the output voltage and the output current of thewireless receiver circuit, and to charge the battery based on the outputvoltage and the output current of the wireless receiver circuit; and adetection circuit, configured to detect the output voltage and/or theoutput current of the wireless receiver circuit.

The method in FIG. 11 includes, at 1110, performing wirelesscommunication with the wireless charging device based on the outputvoltage and/or the output current of the wireless receiver circuitdetected by the detection circuit, to adjust a transmitting power of thewireless charging device, such that the output voltage and/or the outputcurrent of the wireless receiver circuit match a charging stage in whichthe battery presently is.

The wireless communication includes any one or more of Bluetoothcommunication, Wi-Fi communication, short-range wireless communicationbased on a high carrier frequency, optical communication, ultrasoniccommunication, ultra-wideband communication and mobile communication.

Alternatively, in some embodiments, performing wireless communicationwith the wireless charging device based on the output voltage and/or theoutput current of the wireless receiver circuit detected by thedetection circuit to adjust the transmitting power of the wirelesscharging device includes: sending an adjustment message to the wirelesscharging device, the adjustment message being configured to instruct thewireless charging device to adjust the output voltage and/or the outputcurrent of the power supply device.

Alternatively, in some embodiments, the charging stage in which thebattery presently is includes at least one of a trickle charging stage,a constant voltage charging stage, and a constant current chargingstage.

Alternatively, in some embodiments, performing wireless communicationwith the wireless charging device based on the output voltage and/or theoutput current of the wireless receiver circuit detected by thedetection circuit to adjust the transmitting power of the wirelesscharging device, such that the output voltage and/or the output currentof the wireless receiver circuit match the charging stage in which thebattery presently is, may include: during the constant voltage chargingstage of the battery, performing wireless communication with thewireless charging device based on the output voltage and/or the outputcurrent of the wireless receiver circuit detected by the detectioncircuit, to adjust the transmitting power of the wireless chargingdevice, such that the output voltage of the wireless receiver circuitmatches a charging voltage corresponding to the constant voltagecharging stage.

Alternatively, in some embodiments, performing wireless communicationwith the wireless charging device based on the output voltage and/or theoutput current of the wireless receiver circuit detected by thedetection circuit to adjust the transmitting power of the wirelesscharging device, such that the output voltage and/or the output currentof the wireless receiver circuit match the charging stage in which thebattery presently is, may include: during the constant current chargingstage of the battery, performing wireless communication with thewireless charging device based on the output voltage and/or the outputcurrent of the wireless receiver circuit detected by the detectioncircuit, to adjust the transmitting power of the wireless chargingdevice, such that the output current of the wireless receiver circuitmatches a charging current corresponding to the constant currentcharging stage.

Alternatively, in some embodiments, the method in FIG. 11 may furtherinclude: sending battery status information to the wireless chargingdevice, such that the wireless charging device adjusts the transmittingpower of the wireless transmitter circuit according to the batterystatus information, in which the battery status information includes apresent electric quantity and/or a present voltage of the battery in thedevice to be charged.

Alternatively, in some embodiments, communication information betweenthe device to be charged and the wireless charging device includes atleast one of: temperature information of the battery; informationindicating a peak value or a mean value of the output current and/or theoutput voltage of the wireless receiver circuit; information indicatingentering overvoltage protection or overcurrent protection; and powertransmission efficiency information configured to indicate a powertransmission efficiency between the wireless transmitter circuit and thewireless receiver circuit.

Alternatively, in some embodiments, the device to be charged furtherincludes a second charging channel provided with a conversion circuit,in which the conversion circuit is configured to receive the outputcurrent of the wireless receiver circuit, to convert the output currentof the wireless receiver circuit, and to charge the battery based onconverted current; the method in FIG. 11 may further include:controlling switch between the first charging channel and the secondcharging channel.

Alternatively, in some embodiments, the method in FIG. 11 may furtherinclude: performing handshake communication with the wireless chargingdevice, controlling the first charging channel to work when thehandshake communication succeeds, and controlling the second chargingchannel to work when the handshake communication fails.

Alternatively, in some embodiments, the method in FIG. 11 may furtherinclude: controlling switch between the first charging channel and thesecond charging channel according to the temperature of the battery.

Alternatively, in some embodiments, the wireless charging devicesupports a first wireless charging mode and a second wireless chargingmode, in which a charging speed of the wireless charging device chargingthe device to be charged in the first wireless charging mode is greaterthan a charging speed of the wireless charging device charging thedevice to be charged in the second wireless charging mode, and themethod in FIG. 11 may further include communicating with the wirelesscharging device to negotiate performing the wireless charging in thefirst wireless charging mode or in the second wireless charging mode.

In above embodiments, it is possible to implement the embodiments fullyor partially by software, hardware, firmware or any other combination.When implemented by software, it is possible to implement theembodiments fully or partially in a form of computer program products.The computer program product includes one or more computer instructions.When the computer program instructions are loaded and executed by thecomputer, procedures or functions according to embodiments of thepresent disclosure are fully or partially generated. The computer may bea general-purpose computer, a special-purpose computer, a computernetwork, or any other programmable device. The computer instructions maybe stored in a computer readable storage medium, or may be transmittedfrom one computer readable storage medium to another computer readablestorage medium. For example, the computer instructions may betransmitted from one website, computer, server or data center to anotherwebsite, computer, server or data center in a wired manner (for example,via coaxial cables, fiber optics, or DSL (digital subscriber line)) orin a wireless manner (for example, via infrared, WiFi or microwave). Thecomputer readable storage medium may be any available medium that areaccessible by the computer, or a data storage device such as a server ora data center integrated with one or more available medium. Theavailable medium may be magnetic medium (for example, floppy disk, harddisk and tape), optical medium (for example, DVD (digital video disc)),or semiconductor medium (for example, SSD (solid state disk)).

Those skilled in the art could be aware that, example units andalgorithm steps described in combination with embodiments disclosedherein may be implemented by electronic hardware, or by a combination ofcomputer software and electronic hardware. Whether these functions areexecuted by hardware or software is dependent on particular use anddesign constraints of the technical solutions. Professionals may adoptdifferent methods for different particular uses to implement describedfunctions, which should not be regarded as going beyond the scope of thepresent disclosure.

In several embodiments provided by the present disclosure, it should beunderstood that, the disclosed system, device and method may beimplemented in other ways. For example, the device embodiments describedabove are merely illustrative. For example, the units are merely dividedaccording to logic functions, and can be divided in other ways in actualimplementation. For example, a plurality of units or components may becombined or may be integrated into another system, or some features maybe ignored or not executed. In addition, the mutual coupling or directcoupling or communication connection illustrated or discussed may be viasome interfaces, or direct coupling or communication connection ofdevices or units may be in an electrical, mechanical, or other form.

The units described as separate components may or may not be physicallyseparated, and the components displayed as units may or may not bephysical units, that is, may be located in one place, or may bedistributed to multiple network units. Some or all of the units may beselected according to practical requirements to achieve the purpose ofthe solution of the embodiment.

Moreover, respective functional units in respective embodiments of thepresent disclosure may be integrated in one processing unit, or therespective units may be separate physical existence, or two or moreunits may be integrated in one unit.

Above description is merely specific implementation of the presentdisclosure. However, the protection scope of the present disclosure isnot limited to this. Any change or substitute that is conceivable bythose skilled in the art should be in the protection scope of thepresent disclosure. Thus, the protection scope of the present disclosureshould be defined as the protection scope of claims.

What is claimed is:
 1. A wireless charging device, comprising: acommunication control circuit, configured to perform wirelesscommunication with a device to be charged during wireless charging ofthe device to be charged; and a wireless transmitter circuit configuredto transmit power of the wireless charging device, wherein atransmitting power of the wireless transmitter circuit is adjusted basedon feedback information of the device to be charged, such that at leastone of an output voltage or an output current of a wireless receivercircuit in the device to be charged satisfies a present chargingrequirement in each stage of a trickle charging stage, a constantvoltage charging stage, and a constant current charging stage forcharging a battery, wherein the present charging requirement comprisesat least one of a target charging voltage or a target charging currentmatching the charging stage in which the battery presently is, in whichthe transmitting power of the wireless transmitter circuit is adjustedwhen at least one of the output voltage or the output current of thewireless receiver circuit does not match at least one of the targetcharging voltage or the target charging current of the charging stage inwhich the battery presently is, until the at least one of the outputvoltage or the output current of the wireless receiver circuit matchesthe at least one of the target charging voltage or the target chargingcurrent of the charging stage in which the battery presently is, whereinthe communication control circuit comprises any one or more of followingmodules for performing wireless communication with the device to becharged: a Bluetooth module, a Wi-Fi module, a short-range wirelesscommunication module based on a high carrier frequency, an opticalcommunication module, an ultrasonic communication module, anultra-wideband communication module and a mobile communication module.2. The wireless charging device according to claim 1, wherein theshort-range wireless communication module based on the high carrierfrequency comprises an integrated circuit IC chip internally packagedwith an extremely high frequency EHF antenna, the optical communicationmodule comprises an infrared communication module.
 3. The wirelesscharging device according to claim 1, further comprising: a voltageconversion circuit, configured to receive an input voltage provided by apower supply device, and convert the input voltage to obtain an outputvoltage and an output current of the voltage conversion circuit; and awireless transmitter circuit, configured to transmit an electromagneticsignal according to the output voltage and the output current of thevoltage conversion circuit.
 4. The wireless charging device according toclaim 3, wherein the communication control circuit is configured toadjust at least one of the output voltage or the output current of thevoltage conversion circuit, so as to adjust a transmitting power of thewireless transmitter circuit.
 5. The wireless charging device accordingto claim 3, wherein the wireless transmitter circuit comprises: aninverter circuit and a resonance circuit; and the communication controlcircuit is configured to at least one of: adjust a duty ratio of theinverter circuit or adjust a resonance frequency of the resonancecircuit, for adjusting a transmitting power of the wireless transmittercircuit.
 6. The wireless charging device according to claim 3, whereinthe communication control circuit is further configured to receivebattery status information sent by the device to be charged duringperforming wireless communication with the device to be charged, toadjust the transmitting power of the wireless transmitter circuitaccording to the battery status information, in which the battery statusinformation comprises at least one of a present electric quantity or apresent voltage of the battery.
 7. The wireless charging deviceaccording to claim 1, further comprising: a charging interface; and awireless transmitter circuit, configured to receive an output voltageand an output current of a power supply device via the charginginterface, and to generate an electromagnetic signal according to theoutput voltage and the output current of the power supply device.
 8. Thewireless charging device according to claim 7, wherein the communicationcontrol circuit is configured to: communicate with the power supplydevice to negotiate a maximum output power of the power supply device;and during the wireless transmitter circuit performing wireless chargingon the device to be charged according to the maximum output power of thepower supply device, adjust a power quantity drawn by the wirelesstransmitter circuit from the maximum output power to adjust thetransmitting power of the wireless transmitter circuit.
 9. The wirelesscharging device according to claim 7, wherein the communication controlcircuit is configured to: communicate with the power supply device toadjust at least one of an output voltage or an output current of thepower supply device, thereby adjusting the transmitting power of thewireless transmitter circuit.
 10. The wireless charging device accordingto claim 9, wherein the communication control circuit is configured to:receive an adjustment message sent by the device to be charged, theadjustment message being configured to instruct the communicationcontrol circuit to adjust at least one of the output voltage or theoutput current of the power supply device.
 11. The wireless chargingdevice according to claim 1, wherein communication information of thewireless communication between the communication control circuit and thedevice to be charged comprises power transmission efficiencyinformation, and the communication control circuit is further configuredto determine an adjustment magnitude of a transmitting power of thewireless charging device according to the power transmission efficiencyinformation.
 12. The wireless charging device according to claim 1,wherein the communication control circuit is further configured toperform wireless communication with the device to be charged todetermine a charging mode, in which the charging mode comprises a firstwireless charging mode and a second wireless charging mode, a chargingspeed of the wireless charging device charging the device to be chargedin the first wireless charging mode is greater than a charging speed ofthe wireless charging device charging the device to be charged in thesecond wireless charging mode.
 13. The wireless charging deviceaccording to claim 1, wherein the communication control circuit isfurther configured to determine a wireless communication mode adopted bythe wireless communication according to detected signal strengths ofrespective wireless communication modes.
 14. A device to be charged,comprising: a battery; a communication control circuit, configured toperform wireless communication with a wireless charging device duringwireless charging of the battery; and a wireless receiver circuitconfigured to receive an electromagnetic signal transmitted by thewireless charging device and to convert the electromagnetic signal to anoutput current and an output voltage of the wireless receiver circuitand to send feedback information of a wireless transmitter circuit ofthe wireless charging device to adjust a transmitting power of awireless transmitter circuit of the wireless charging device, such thatat least one of an output voltage or an output current of a wirelessreceiver circuit in the device to be charged satisfies a presentcharging requirement in each stage of a trickle charging stage, aconstant voltage charging stage, and a constant current charging stagefor charging the battery, wherein the present charging requirementcomprises at least one of a target charging voltage or a target chargingcurrent matching the charging stage in which the battery presently is,in which the transmitting power of the wireless transmitter circuit isadjusted when at least one of the output voltage or the output currentof the wireless receiver circuit does not match at least one of thetarget charging voltage or the target charging current of the chargingstage in which the battery presently is, until the at least one of theoutput voltage or the output current of the wireless receiver circuitmatches the at least one of the target charging voltage or targetcharging current of the charging stage in which the battery presentlyis, wherein the communication control circuit comprises any one or moreof following modules for performing wireless communication with thedevice to be charged: a Bluetooth module, a Wi-Fi module, a short-rangewireless communication module based on a high carrier frequency, anoptical communication module, an ultrasonic communication module, anultra-wideband communication module and a mobile communication module.15. The device to be charged according to claim 14, further comprising:a detection circuit, configured to detect at least one of a voltage or acurrent entering the battery during the wireless charging; wherein thecommunication control circuit is configured to perform wirelesscommunication with the wireless charging device according to at leastone of the voltage or current detected by the detection circuit, suchthat the wireless charging device adjusts a transmitting power, toadjust at least one of the voltage or the current entering the battery.16. The device to be charged according to claim 14, further comprising:a wireless receiver circuit, configured to receive an electromagneticsignal transmitted by the wireless charging device, and to convert theelectromagnetic signal to an output current and an output voltage of thewireless receiver circuit; and a first charging channel, configured toreceive the output voltage and the output current of the wirelessreceiver circuit, and to charge the battery based on an output voltageand an output current of the first charging channel.
 17. The device tobe charged according to claim 16, further comprising: a second chargingchannel, provided with a conversion circuit, in which the conversioncircuit is configured to receive the output current and the outputvoltage of the wireless receiver circuit, to convert at least one of theoutput current or the output voltage of the wireless receiver circuit,and to charge the battery based on at least one of a converted currentor a converted voltage; wherein the communication control circuit isfurther configured to control switch between the first charging channeland the second charging channel.
 18. The device to be charged accordingto claim 17, wherein the communication control circuit is furtherconfigured to perform handshake communication with the wireless chargingdevice, to control the first charging channel to work when the handshakecommunication succeeds, and to control the second charging channel towork when the handshake communication fails.
 19. The device to becharged according to claim 17, wherein the communication control circuitis further configured to control switch between the first chargingchannel and the second charging channel according to a temperature ofthe battery.
 20. A wireless charging method, applicable to a wirelesscharging device, comprising: transmitting power of the wireless chargingdevice, wherein a transmitting power of the wireless charging device isadjusted based on feedback information of a device to be charged, suchthat at least one of an output voltage or an output current of awireless receiver circuit in the device to be charged satisfies apresent charging retirement in each stage of a trickle charging stage, aconstant voltage charging stage, and a constant current charging stagefor charging a battery, wherein the present charging requirementcomprises at least one of a target charging voltage or a target chargingcurrent matching the charging stage in which the battery presently is,in which the transmitting power of the wireless transmitter circuit isadjusted when at least one of the output voltage or the output currentof the wireless receiver circuit does not match it least one of thetarget charging voltage or the target charging current of the chargingstage in which the battery presently is, until the at least one of theoutput voltage or the output current of the wireless receiver circuitmatches the at least one of the target charging voltage or the targetcharging current of the charging stage in which the battery presentlyis, and performing wireless communication with a device to be chargedduring wireless charging of the device to be charged, wherein thewireless communication comprises one or more of Bluetooth communication,Wi-Fi communication, short-range wireless communication based on a highcarrier frequency, optical communication, ultrasonic communication,ultra-wideband communication and mobile communication.